Expressed protein ligation to obtain selectively modified aldo/keto reductases

Specific enzyme immobilization has moved into the focus for many applications in biochemical research fields. Expressed Protein Ligation (EPL) has been proven to be ideal to selectively label proteins at single positions. Applying this technique to enzymes of the aldo/keto reductase superfamily provides a new approach to generate native or modified redox enzymes for direct and indirect immobilization.     

Chicken muscle aldose reductase: purification, properties and relationship to other chicken aldo/keto reductases

An enzyme that catalyzes the NADPH-dependent reduction of a wide range of aromatic and hydroxy-aliphatic aldehydes was purified from chicken breast muscle. This enzyme shares many properties with mammalian aldose reductases including molecular weight, relative substrate specificity, Michaelis constants, an inhibitor specificity. Therefore, it seems appropriate to call this enzyme an aldose reductase (EC 1.1.1.21). Chicken muscle aldose reductase appears to be kinetically identical to an aldose reductase that has been purified from chicken kidney (Hara et al., Eur. J. Biochem. 133, 207-214) and to hen muscle L-glycol dehydrogenase (Bernado et al., Biochim. biophys. Acta 659, 189-198). The association of this aldose reductase with muscular dystrophy in the chick is discussed.     

Isolation of a yeast gene encoding a protein homologous to the human Tat-binding protein TBP-1.

We have cloned a putative yeast homolog of the gene encoding the human Tat-binding protein, TBP-1. The gene termed TBPY encodes a 45,243-dalton protein displaying a heptad repeat of hydrophobic amino acids reminiscent of a leucine zipper. Secondary structure predictions suggest the possibility of formation of an amphipathic helix that could further be organized into a coiled-coil. Additionally, the protein product of TBPY shows amino acid signatures characteristic of a large family of RNA and DNA helicases. We propose that the hydrophobic region of yTBP-1 participates in self-dimerization or heterodimerization.     

Characterization of the yeast BMH1 gene encoding a putative protein homologous to mammalian protein kinase II activators and protein kinase C inhibitors.

We describe the identification and characterization of the BMH1 gene from the yeast Saccharomyces cerevisiae. The gene encodes a putative protein of 292 amino acids which is more than 50% identical with the bovine brain 14-3-3 protein and proteins isolated from sheep brain which are strong inhibitors of protein kinase C. Disruption mutants and strains with the BMH1 gene on multicopy plasmids have impaired growth on minimal medium with glucose as carbon source, i.e. a 30-50% increase in generation time. These observations suggest a regulatory function of the bmh1 protein. In contrast to strains with an intact or a disrupted BMH1 gene, strains with the BMH1 gene on multicopy plasmids hardly grew on media with acetate or glycerol as carbon source.     

A gene encoding a yeast equivalent of mammalian NADPH-adrenodoxin oxidoreductases

Adrenodoxin oxidoreductase (ADR) and adrenodoxin (ADX) are the two proteins involved in electron transport to mammalian mitochondrial P-450s capable of steroid modifications. The cloning and sequencing of a S. cervisiae ADR homologue (YADR) is presented here. The YADR protein sequence shares 36 and 37% of identical amino acids with human and bovine ADR respectively. The physiological role of this ADR homologue in yeast is unknown. We intend to study the interaction of this YADR with bovine ADX in vitro and in vivo.     

Isolation and sequencing of NOP1. A yeast gene encoding a nucleolar protein homologous to a human autoimmune antigen

We have identified the gene for the yeast nucleolar protein p38 and deduced the primary structure of p38 from its sequence. We propose the name NOP1 (nucleolar protein 1) for this gene. NOP1 encodes a 327 amino acid protein of 34,470 daltons and is flanked by potential promoter and polyadenylation sequences. Blot analyses indicate that the mRNA transcribed from NOP1 is approximately 1.3 kilobases in size and that there is one NOP1 gene per haploid genome. The amino-terminal sequence of p38 is homologous with the 31 known amino-terminal residues of the autoimmune antigen fibrillarin, confirming the previously observed similarity between p38 and this mammalian nucleolar protein. Consistent with this, p38 cross-reacts with serum from a patient with the autoimmune disease scleroderma. A putative nuclear localization signal can be identified in p38. Interestingly, a repetitive amino acid sequence motif begins near the amino terminus of p38. This motif is approximately 80 residues long, is rich in glycine and arginine, and shows striking sequence homology to mammalian nucleolins and certain nucleic acid binding proteins.     

An Arabidopsis gene homologous to mammalian and insect genes encoding the largest proteasome subunit

A gene encoding a protein with extensive homology to the largest subunit of the multicatalytic proteinase complex (proteasome) has been identified in Arabidopsis thaliana. This gene, referred to as AtPSM30, is entirely encompassed within a previously characterized radiation-induced deletion, which may thus provide the first example of a proteasome null mutation in a higher eukaryote. However, the growth rate and fertility of Arabidopsis plants do not appear to be significantly affected by this mutation, even though disruption experiments in yeast have shown that most proteasome subunits are essential. Analysis of mRNA levels in developing seedlings and mature plants indicates that expression of AtPSM30 is differentially regulated during development and is slightly induced in response to stress, as has been observed for proteasome genes in yeast, Drosophila, and mammals. Southern blot analysis indicates that the Arabidopsis genome contains numerous sequences closely related to AtPSM30, consistent with recent reports of at least two other proteasome genes in Arabidopsis. A comparison of the deduced amino acid sequences for all proteasome genes reported to date suggests that multiple proteasome subunits evolved in eukaryotes prior to the divergence of plants and animals.GenBank accession number: M98495     

Characterisation of an mRNA encoding a human ribosomal protein homologous to the yeast L44 ribosomal protein

We describe the isolation and characterisation of a full-length cDNA sequence (pZH-21) of a human ribosomal protein (rp) mRNA isolated from a cDNA library constructed from the human ZR-75-1 mammary tumour cell-line. The predicted protein is highly basic and shows 72% homology at the amino acid (aa) level with yeast rp L44. Comparative RNA blotting of ZR-75-1 poly(A)+ RNA isolated from cells cultured in the presence of the anti-oestrogen tamoxifen demonstrates the presence of a number of mRNA species whose concentration is elevated co-ordinately 5-6-fold in the presence of 17beta-oestradiol. Insulin in the presence of tamoxifen, also enhanced rp mRNA levels suggesting increased levels are a reflection of cell proliferation as opposed to specific hormonal regulation. Genomic analysis demonstrates the presence of a family of related human sequences, and homology with rat and guinea pig rp genes, but not yeast DNA. The conservation of rp aa sequence, in the absence of detectable homology at the nucleotide (nt) level, points to an important common functional role of the L44 protein in ribosome structure and function in man and yeast.     

A C. elegans gene encodes a protein homologous to mammalian calreticulin.

The gene encoding a C. elegans homologue of the mammalian reticuloplasmin, calreticulin, was cloned and sequenced and the amino-acid sequence of its product deduced. The coding region of the gene comprises three exons separated by introns of 95 and 55 nucleotides, followed by either 158 or 279 bases of 3' non-coding sequence before putative polyadenylation signals. The precursor protein of 395 residues includes an N-terminal signal sequence of 13 residues. The C-terminus has the ER retention signal HDEL preceded by a polyacidic zone similar to known mammalian calreticulins. The sequence shows a 61% identity with mouse calreticulin, increasing to 82% in the proline-rich region of the molecule. Comparison of the C. elegans sequence with the calreticulin-related antigen RAL-1 of Oncocerca volvulus shows 73% identity, excluding the calreticulin C-terminal region. The sequence of this region differs markedly from RAL-1 where the parasite protein has a polybasic stretch and no ER retention signal. The C. elegans gene described here and designated crt-1 was mapped to a region towards the left-hand end of Chromosome V on the physical map of the genome. Southern blotting of genomic DNA indicates that in C. elegans the calreticulin homologue exists in only one form as the product of a single gene.     

A subunit of mammalian signal peptidase is homologous to yeast SEC11 protein

Canine signal peptidase consists of a complex of five proteins (Evans, A. E., Gilmore, R., and Blobel, G. (1986) Proc. Natl. Acad. Sci. U.S.A. 83, 581-585). A cDNA encoding the 21-kDa subunit of the signal peptidase complex was isolated from a liver cDNA library using an 88-base pair probe, generated by the polymerase chain reaction. The 820-base pair cDNA was sequenced and found to encode a protein of 21,585 daltons. The deduced amino acid sequence from the canine cDNA was found to be 47% identical to the yeast SEC11 protein. SEC11 has been shown to be required for signal peptide cleavage, normal rate of secretion, and cell survival in Saccharomyces cerevisiae (B?hni, P. C., Deshaies, R. J., and Schekman, R. W. (1988) J. Cell Biol. 106, 1035-1042). It is, therefore, likely that the 21-kDa subunit of signal peptidase complex is the structural and functional homologue of the yeast SEC11 gene product.     

An Arabidopsis gene homologous to mammalian and insect genes encoding the largest proteasome subunit

A gene encoding a protein with extensive homology to the largest subunit of the multicatalytic proteinase complex (proteasome) has been identified in Arabidopsis thaliana. This gene, referred to as AtPSM30, is entirely encompassed within a previously characterized radiation-induced deletion, which may thus provide the first example of a proteasome null mutation in a higher eukaryote. However, the growth rate and fertility of Arabidopsis plants do not appear to be significantly affected by this mutation, even though disruption experiments in yeast have shown that most proteasome subunits are essential. Analysis of mRNA levels in developing seedlings and mature plants indicates that expression of AtPSM30 is differentially regulated during development and is slightly induced in response to stress, as has been observed for proteasome genes in yeast, Drosophila, and mammals. Southern blot analysis indicates that the Arabidopsis genome contains numerous sequences closely related to AtPSM30, consistent with recent reports of at least two other proteasome genes in Arabidopsis. A comparison of the deduced amino acid sequences for all proteasome genes reported to date suggests that multiple proteasome subunits evolved in eukaryotes prior to the divergence of plants and animals.     

PRS3 encoding an essential subunit of yeast proteasomes homologous to mammalian proteasome subunit C5.

We found by computer analysis that a putative yeast proteasome subunit gene named PRS3 that encodes a protein very similar to subunit C5 of rat and human proteasomes is located immediately 3' to the ERD2 gene of Saccharomyces cerevisiae. The similarity of the primary structures of the two suggests that this subunit may have a common function in proteasomes of all eukaryotes. The protein, deduced from the open reading frame of PRS3, consists of 242 amino acid residues with a calculated molecular weight of 27,077. Chromosomal disruption of the PRS3 gene created a recessive lethal mutation. Physical mapping by hybridization to intact S. cerevisiae chromosomal DNA showed that the PRS3 gene is located on chromosome II, unlike two other subunit genes, PRS1 and PRS2, which are located on chromosomes XV and VII, respectively. These findings indicate that the PRS3 protein is a subunit of yeast proteasomes that is essential for cell viability.     

A yeast gene coding for a putative protein kinase homologous to cdc25 suppressing protein kinase

A yeast gene termed YKR coding for a putative protein kinase was isolated by using the cloned cDNA for rabbit protein kinase C as a hybridization probe. The encoded protein (YKR), composed of 380 amino acid residues, shows extensive sequence homology to serine/threonine-specific protein kinases from various species in the approx. 320 C-terminal amino acid residues, strongly suggesting that YKR is endowed with a protein kinase activity. The observed homologies to the cdc25 suppressing protein kinase from yeast, the catalytic subunit of mammalian cAMP-dependent protein kinase, and mammalian protein kinase C were 76, 48 and 37%, respectively. Gene replacement experiments showed that YKR itself is not essential for cell proliferation.     

An archaebacterial gene from Methanococcus vannielii encoding a protein homologous to the ribosomal protein L10 family

An open reading frame upstream of the Methanococcus vannielii L12 gene has been detected. The beginning of this open reading frame agrees with the N-terminal region of a protein (MvaL10) which has been isolated from the 50 S ribosomal subunit of M. vannielii and sequenced. The length of this gene is 1008 nucleotides, coding for 336 amino acids. Excellent sequence similarities were found to the L10-like ribosomal proteins from Halobacterium halobium and man. The N-terminal part of the MvaL10 protein shows significant sequence similarities to the E. coli L10 protein. MvaL10 is more than twice as long as E. coli L10 but is of length similar to those of the homologous halobacterial and human proteins. Interestingly, the C-terminal region of MvaL10 shows exceptionally high similarity to the C-terminal sequence of the MvaL12 protein. This is not the case for the E. coli proteins but was also observed for the human, Halobacterium and Sulfolobus proteins.