Expression and Secretion of Barley Cysteine Endopeptidase B and Cellobiohydrolase I in Trichoderma reesei.

Localization of expression and secretion of a heterologous barley cysteine endopeptidase (EPB) and the homologous main cellobiohydrolase I (CBHI) in a Trichoderma reesei transformant expressing both proteins were studied. The transformant was grown on solid medium with Avicel cellulose and lactose to induce the cbh1 promoter for the synthesis of the native CBHI and the recombinant barley protein linked to a cbh1 expression cassette. Differences in localization of expression between the two proteins were clearly indicated by in situ hybridization, indirect immunofluorescence, and immunoelectron microscopy. In young hyphae, native-size recombinant epb mRNA was localized to apical compartments. In older cultures, it was also seen in subapical compartments but not in hyphae from the colony center. The recombinant EPB had a higher molecular weight than the native barley protein, probably due to glycosylation and differential processing in the fungal host. As was found with its transcripts, recombinant EPB was localized in apical and subapical compartments of hyphae. The cbh1 mRNA and CBHI were both localized to all hyphae of a colony, which suggests that the endogenous CBHI was also secreted from these. In immunoelectron microscopy, the endoplasmic reticulum and spherical vesicles assumed to contribute to secretion were labeled by both CBHI and EPB antibodies while only CBHI was localized in elongated vesicles close to the plasma membrane and in hyphal walls. The results indicate that in addition to young apical cells, more mature hyphae in a colony may secrete proteins.

Expression of Barley Endopeptidase B in Trichoderma reesei.

The gene for barley endopeptidase B (EPB) has been expressed in the filamentous fungus Trichoderma reesei from the cbh1 promoter. The EPB signal sequence allowed secretion of over 90% of the recombinant protein. Yields reached about 500 mg of immunoreactive protein per liter and exceeded values for any other protein derived from a higher eukaryotic organism produced in T. reesei.

Protein purification, and cloning and characterization of the cDNA and gene for xylose isomerase of barley.

The first eukaryotic xylose isomerase protein was purified from barley Hordeum vulgare. The enzyme requires Mn2+ for its activity and is fairly thermostable, with the optimum temperature being 60 degrees C. It showed maximum activity over a broad pH range (7.0-9.0). The molecular mass of the monomer was about 50,000 Da based on the SDS/PAGE, and the calculated value from the cDNA-deduced polypeptide sequence was 53,620 Da. A relative mass estimation of 100,000 Da was obtained from the Superose 12 chromatography, suggesting that the barley enzyme is a dimer. The cloned corresponding cDNA sequence of 1710 nucleotides encoded a polypeptide of 480 amino acids. The genomic sequence of 4473 nucleotides, revealed that the isomerase gene contained 20 introns, all starting with GT and ending with AG. One large intron was located in the 5'untranslated region. The barley isomerase has an insertion of about 40 residues at its amino terminus when compared to the prokaryotic cluster (family) II isomerases; cluster (family) I and cluster (family) II isomerases vary from the former in an insertion of around 50 residues at their amino termini. Comparison of the barley protein with the prokaryotic isomerases shows that the conserved catalytic and metal binding regions are also well conserved in barley.

Cloning, sequencing and enhanced expression of the Trichoderma reesei endoxylanase II (pI 9) gene xln2.

The Trichoderma reesei xln2 gene coding for the pI9.0 endoxylanase was isolated from the wild-type strain QM6a. The gene contains one intron of 108 nucleotides and codes for a protein of 223 amino acids in which two putative N-glycosylation target sites were found. Three different T. reesei strains were transformed by targeting a construct composed of the xln2 gene, including its promoter, to the endogenous cbh1 locus. Highest overall production levels of xylanase were obtained using T. reesei ALKO2721, a genetically engineered strain, as a host. Integration into the cbh1 locus was not required for enhanced expression under control of the xln2 promoter.

A rapid method to study heterogeneous gene expression in liver by direct assay of messenger RNA from periportal and perivenous cell lysates.

To study zonation of liver gene expression, we obtained periportal or perivenous rat liver cell lysates virtually devoid of nuclear material by site-directed digitonin infusion in situ. Total RNA was isolated, messenger RNAs were reverse transcribed and complementary DNAs were assayed after polymerase chain reaction-mediated amplification. The zonal distribution of messenger RNAs of alcohol dehydrogenase (little zonation), glutamine synthetase (perivenous) and cytochrome P-450 2E1 (perivenous) messenger RNAs, as analyzed by this technique, were found to be similar to the distribution of corresponding apoproteins. Using appropriate primers or complementary DNAs, zonation of many different messenger RNAs can be determined from the same sample by this simple and rapid method.

Molecular analysis of barley mutants deficient in chloroplast glutamine synthetase.

A barley leaf cDNA library has been screened with two oligonucleotide probes designed to hybridize to conserved sequences in glutamine synthetase (GS) genes from higher plants. Two GS cDNA clones were identified as hybridizing strongly to one or both probes. The larger clone (pcHvGS6) contained a 1.6 kb insert which was shown by primer extension analysis to be an almost full-length cDNA. Both clones were more closely related to cDNAs for the chloroplast form of GS (GS2) from pea and Phaseolus vulgaris than to cDNAs for the cytosolic form (GS1). A sequence identical to an N-terminal sequence determined from a purified preparation of the mature GS2 polypeptide (NH2-XLGPETTGVIQRMQQ) was found in the pcHvGS6-encoded polypeptide at residues 46-61, indicating a pre-sequence of at least 45 amino acids. The pre-sequence has only limited sequence homology to the pre-sequences of pea and P. vulgaris GS2 subunits, but is similarly rich in basic residues and possesses some of the structural features common to the targeting sequences of other chloroplast proteins. The molecular lesions responsible for the GS2-deficient phenotypes of eight photorespiratory mutants of barley were investigated using a gene-specific probe from pcHvGS6 to assay for GS2 mRNA, and an anti-GS antiserum to assay for GS2 protein. Three classes of mutants were identified: class I, in which absence of cross-reacting material was correlated with low or undetectable levels of GS2 mRNA; class II, which had normal or increased levels of GS2 mRNA but very little GS2 protein; and class III, which had significant amounts of GS2 protein but little or no GS2 activity.

Primary structure and differential expression of glutamine synthetase genes in nodules, roots and leaves of Phaseolus vulgaris.

In plants, glutamine synthetase (GS) is the enzyme primarily responsible for the assimilation of ammonia into organic nitrogen. In Phaseolus vulgaris a number of isoenzymic forms of GS are found, each of which consists of eight subunits of mol. wt 41 000-45 000. The GS subunits of P. vulgaris have previously been shown to be encoded by a small multigene family and a partial cDNA clone for a nodule-specific GS subunit has been obtained. We report here the isolation and nucleotide sequencing of two essentially full-length GS cDNA clones (pR-1 and pR-2) from a root cDNA library and the deduced amino acid sequences of the corresponding GS subunits (355 amino acid residues each). The coding sequences of pR-1 and pR-2 are closely related (80% nucleotide homology, 88% amino acid homology), but their 5'- and 3'-untranslated regions have diverged almost completely. Both pR-1 and pR-2 are related to, but distinct from, the nodule GS clone, pcPvNGS-01 (or pN-1). Hybridization to genomic Southern blots showed that the three GS mRNAs are encoded by three seperate genes and indicated the existence of a fourth class of GS gene. An S1 nuclease protection assay demonstrated the presence of R-1 and R-2 mRNA in both roots and leaves and confirmed that expression of the N-1 gene is nodule-specific. Expression of the R-1 and R-2 genes in the roots did not change significantly during nodulation. However, only the R-1 gene is expressed in the nodules themselves, indicating that the R-2 gene is specifically repressed during nodule development.

Glutamine synthetase of Phaseolus vulgaris L.: organ-specific expression of a multigene family.

A recombinant plasmid (pcPvNGS-01) containing sequences related to glutamine synthetase (GS) has been identified from a cDNA library constructed from poly (A)+ RNA isolated from root nodules of Phaseolus vulgaris L. The identification of this recombinant relied on the observations that: (a) the clone hybridized strongly to purified GS mRNA; (b) in hybrid-select translation experiments, the clone selected mRNA that produced a polypeptide identical in molecular weight to purified GS subunits which was immunoprecipitated with anti-GS-antiserum; and (c) the translated nucleotide sequence of the cloned cDNA was homologous to a partial amino acid sequence of higher plant GS. The cloned cDNA hybridized to poly (A)+ RNA of different mobilities from leaves, roots, and nodules of P. vulgaris. In RNA "dot" blots washed at different stringencies, differences were observed both in the relative amounts of GS mRNA in different tissues and in the strength of their hybridization to the cDNA probe. The cloned probe hybridized to several fragments of restricted P. vulgaris DNA but not to DNA from Rhizobium phaseoli. These results suggest that GS is coded for by a small multigene family showing organ-specific expression.