Inheritance of alleles for glutelin alpha-2 subunit genes in rice and identification of their corresponding cDNA clone

Rice glutelins consist of acidic (alpha) and basic (beta) subunits which are further separated into three polypeptide components assigned as alpha-1, alpha-2, and alpha-3 subunit components and beta-1, beta-2 and beta-3 subunit components. Nine rice mutant lines with a decreased amount of the glutelin alpha-2 subunit component (alpha-2L) were obtained by screening about 6,800 potential mutant lines derived from the fertilized egg treatment with N-methyl-N-nitrosourea (MNU) using the SDS-PAGE method. The mutants were classified into three types of the increased alpha-1 subunit (alpha-1H/alpha-2L), the decreased beta-2 subunit (beta-2L/alpha-2L) and the increased alpha-3 subunit (alpha-3H/alpha-2L) represented by EM278, CM1707 and EM659, respectively. Iso-electric focus (IEF) analysis revealed that all of the mutants had an extremely low amount of a polypeptide with a 6.71 pI value, whereas a polypeptide with either a 6.50 pI value or with a 6.90 pI value increased significantly in alpha-1H/alpha-2L mutants or in alpha-3H/alpha-2L mutants, respectively. The beta-2L/alpha-2L mutants had a decreased amount of a basic polypeptide with a 8.74 pI value. Genetic analysis revealed that the three types of mutants were controlled by a single incomplete dominant gene respectively, and the three are alleles. The gene was temporarily named glu4, which was found to be located on chromosome 1 linked with the eg and spl6 genes. Two-dimensional electrophoresis analysis revealed that the glu4 encoded polypeptides of pI 6.71/alpha-2 and pI 8.74/beta-2. Amino acid sequence analysis suggested that the mutated acidic polypeptide was the product of a GluA subfamily gene. Northern and RT-PCR analyses revealed that glu4 corresponded to the GluA-1 gene.     

Micro-heterogeneity of Storage Glutelin in Rice Seed (in English)

Nine rice Oryza sativa L.） mutant lines lacking the seed storage glutelin α-2 subunit were obtained from the progenies of fertilized egg cells treated with N-methy-N-nitrosourea (MNU). The mutants could be classified into three types: the α-1 subunit increased type (α-1H/α-2L), decreased the β-2 subunit decreased type (β-2L/α-2L) and the α-3 subunit increased type (α-3H/α-2L) according to their SDS-PAGE profiles. Two-dimensional electrophoresis analysis revealed that all of the mutants lacked a polypeptide of pI 6.71/α-2, while new polypeptides of pI 6.50/α-1 and pI 6.90/α-3 formed in α-1H/α-2L and α-3H/α-2L mutants respectively. Although the β-2L/α-2L mutants did not form new polypeptide, their pI 8.74/β-2 polypeptide was also decreased, suggesting that the two polypeptides decreased in β-2L/α-2L mutants might derive from the same glutelin precursor. These mutant lines are very useful in studying genetic characterisation,the mechanism of genetic regulation on biosynthesis, gene function and proteomics of rice seed storage glutelin.     

Seed Storage Glutelin α-2 Subunit Lacking Mutants in Rice

Nine rice Oryza sativa L.） mutant lines lacking the seed storage glutelin α-2 subunit were obtained from the progenies of fertilized egg cells treated with N-methy-N-nitrosourea (MNU). The mutants could be classified into three types: the α-1 subunit increased type (α-1H/α-2L), decreased the β-2 subunit decreased type (β-2L/α-2L) and the α-3 subunit increased type (α-3H/α-2L) according to their SDS-PAGE profiles. Two-dimensional electrophoresis analysis revealed that all of the mutants lacked a polypeptide of pI 6.71/α-2, while new polypeptides of pI 6.50/α-1 and pI 6.90/α-3 formed in α-1H/α-2L and α-3H/α-2L mutants respectively. Although the β-2L/α-2L mutants did not form new polypeptide, their pI 8.74/β-2 polypeptide was also decreased, suggesting that the two polypeptides decreased in β-2L/α-2L mutants might derive from the same glutelin precursor. These mutant lines are very useful in studying genetic characterisation,the mechanism of genetic regulation on biosynthesis, gene function and proteomics of rice seed storage glutelin.     

新的水稻谷蛋白α—1亚基缺失突变体

从水稻受精卵MNU处理后代中获得4个谷蛋白α－1亚基缺失突变品系。SDS－PAGE和IEF分析表明这些突变体在共同缺失1条pI6.82多肽的同时,或形成新的多肽,或其他多肽表现量增加,这些突变体是由结构基因控制的,IEF分析同时显示2条多肽pI6.82和pI8.58源自同一条谷蛋白前驱体。这4个突变体对于改良水稻谷蛋白品质、研究谷蛋白生物合成遗传调控机制以及揭示谷蛋白基因功能是不可多得的研究材料。     

Knockout of glutelin genes which form a tandem array with a high level of homology in rice by gamma irradiation

In the course of evolution, a gene is often duplicated in tandem, resulting in a functional redundancy. The analysis of function of these genes by raising double mutant might be difficult because they are very tightly linked. We described here a mutant of such a tandem duplicated gene. glu1 is a gamma-ray-induced rice mutant, which lacks an acidic subunit of glutelin, a major seed storage protein. We found that glu1 harbors a 129.7-kb deletion involving two highly similar and tandem repeated glutelin genes, GluB5 and GluB4. The deletion eliminated the entire GluB5 and GluB4 gene except half of the first exon of GluB5. GluB5 and GluB4 have the same amino acid sequence in the acidic subunit, suggesting that only the mutation involving both GluB5 and GluB4 results in the lack of the glutelin acidic subunit deleted in glu1. Our finding suggests that gamma-ray can be an effective mutagen to analyze tandem repeated and functionally redundant genes.     

The vacuolar processing enzyme OsVPE1 is required for efficient glutelin processing in rice

Rice ( Oryza sativa L.) accumulates prolamines and glutelins as its major storage proteins. Glutelins are synthesized on rough endoplasmic reticulum as 57-kDa precursors; they are then sorted into protein storage vacuoles where they are processed into acidic and basic subunits. We report a novel rice glutelin mutant, W379 , which accumulates higher levels of the 57-kDa glutelin precursor. Genetic analysis revealed that the W379 phenotype is controlled by a single recessive nuclear gene. Using a map-based cloning strategy, we identified this gene, OsVPE1 , which is a homolog of the Arabidopsis βVPE gene. OsVPE1 encodes a 497-amino-acid polypeptide. Nucleotide sequence analysis revealed a missense mutation in W379 that changes Cys269 to Gly. Like the wild-type protein, the mutant protein is sorted into vacuoles; however, the enzymatic activity of the mutant OsVPE1 is almost completely eliminated. Further, we show that OsVPE1 is incorrectly cleaved, resulting in a mature protein that is smaller than the wild-type mature protein. Taken together, these results demonstrate that OsVPE1 is a cysteine protease that plays a crucial role in the maturation of rice glutelins. Further, OsVPE1 Cys269 is a key residue for maintaining the Asn-specific cleavage activity of OsVPE1.     

Sequence analysis of a gene cluster involved in metabolism of 2,4,5-trichlorophenoxyacetic acid by Burkholderia cepacia AC1100.

Burkholderia cepacia AC1100 utilizes 2,4,5-trichlorophenoxyacetic acid (2,4,5-T) as a sole source of carbon and energy. PT88 is a chromosomal deletion mutant of B. cepacia AC1100 and is unable to grow on 2,4,5-T. The nucleotide sequence of a 5.5-kb chromosomal fragment from B. cepacia AC1100 which complemented PT88 for growth on 2,4,5-T was determined. The sequence revealed the presence of six open reading frames, designated ORF1 to ORF6. Five polypeptides were produced when this DNA region was under control of the T7 promoter in Escherichia coli; however, no polypeptide was produced from the fourth open reading frame, ORF4. Homology searches of protein sequence databases were performed to determine if the proteins involved in 2,4,5-T metabolism were similar to other biodegradative enzymes. In addition, complementation studies were used to determine which genes were essential for the metabolism of 2,4,5-T. The first gene of the cluster, ORF1, encoded a 37-kDa polypeptide which was essential for complementation of PT88 and showed significant homology to putative trans-chlorodienelactone isomerases. The next gene, ORF2, was necessary for complementation and encoded a 47-kDa protein which showed homology to glutathione reductases. ORF3 was not essential for complementation; however, both the 23-kDa protein encoded by ORF3 and the predicted amino acid sequence of ORF4 showed homology to glutathione S-transferases. ORF5, which encoded an 11-kDa polypeptide, was essential for growth on 2,4,5-T, but the amino acid sequence did not show homology to those of any known proteins. The last gene of the cluster, ORF6, was necessary for complementation of PT88, and the 32-kDa protein encoded by this gene showed homology to catechol and chlorocatechol-1,2-dioxygenases.     

P61 Protein from a Male Sterile Mutant of Rice is an Isoform of the Chloroplast ATPase β Subunit

P61 was a protein identified from chloroplasts of Nongken 58S, a male sterile mutant of rice (Oryza sativa L. ssp. japonica). Microsequence analysis has revealed that its N-terminal sequence was identical to N-termini of ATPase β subunits of chloroplasts from rice and barley. The antiserum produced using ATPase β subunit from maize specifically recognized P61. P61 had the same molecular weight as the chloroplast ATPase β subunit of wild-type rice “Nongken 58”, but had different isoelectric point (pI) from this β　subunit. P61 was more basic than this β subunit. Thus, P61 would be identified as an isoform of the chloroplast ATPase β subunit of rice, named β1. Genetic analysis with a F2 population of Nongken 58SדNongken 58” showed that a single recessive genic gene regulated the formation of β1.     

Characterization and expression of the plasmid-borne bedD gene from Pseudomonas putida ML2, which codes for a NAD+-dependent cis-benzene dihydrodiol dehydrogenase.

The catabolic plasmid pHMT112 in Pseudomonas putida ML2 contains the bed gene cluster encoding benzene dioxygenase (bedC1C2BA) and a NAD+-dependent dehydrogenase (bedD) required to convert benzene into catechol. Analysis of the nucleotide sequence upstream of the benzene dioxygenase gene cluster (bedC1C2BA) revealed a 1,098-bp open reading frame (bedD) flanked by two 42-bp direct repeats, each containing a 14-bp sequence identical to the inverted repeat of IS26. In vitro translation analysis showed bedD to code for a polypeptide of ca. 39 kDa. Both the nucleotide and the deduced amino acid sequences show significant identity to sequences of glycerol dehydrogenases from Escherichia coli, Citrobacter freundii, and Bacillus stearothermophilus. A bedD mutant of P. putida ML2 in which the gene was disrupted by a kanamycin resistance cassette was unable to utilize benzene for growth. The bedD gene product was found to complement the todD mutation in P. putida 39/D, the latter defective in the analogous cis-toluene dihydrodiol dehydrogenase. The dehydrogenase encoded by bedD) was overexpressed in Escherichia coli and purified. It was found to utilize NAD+ as an electron acceptor and exhibited higher substrate specificity for cis-benzene dihydrodiol and 1,2-propanediol compared with glycerol. Such a medium-chain dehydrogenase is the first to be reported for a Pseudomonas species, and its association with an aromatic ring-hydroxylating dioxygenase is unique among bacterial species capable of metabolizing aromatic hydrocarbons.     

A rice glutelin and a soybean glycinin have evolved from a common ancestral gene

A cDNA clone covering the entire coding region for a glutelin subunit precursor has been identified from a library of endosperm-developing rice cDNA clones using a mixed oligodeoxynucleotide probe, and then by immunoprecipitation of hybrid-selected translation product with an antiserum against the acidic polypeptides of the glutelin. Analysis of the cDNA insert revealed that rice glutelin is synthesized as precursor polypeptides which undergo post-translational processing to form the nonrandom polypeptide pairs, like glycinin precursors of soybean. By comparing the predicted protein sequence of this precursor from monocots with that of glycinin A1aB1b precursor from dicots, it was found that the overall 32% of the amino acid positions are identical in both proteins. Because regions which show identities are dispersed throughout both molecules, the similarity is not due to convergent evolution, but to divergence evolution from a common ancestral gene.     

Sequence of the small subunit of yeast carbamyl phosphate synthetase and identification of its catalytic domain

The yeast gene CPA1 coding for the small subunit of arginine-specific carbamyl phosphate synthetase has been cloned by complementation of a cpa 1 mutant with a plasmid library of total yeast chromosomal DNA. Two of the plasmids, pJL113/ST4 and pJL113/ST15, contain DNA inserts in opposite orientations with overlapping sequences of 2.6 kilobases. The nucleotide sequence of a 2.2-kilobase region of the DNA insert carrying the CPA1 gene has been determined. The CPA1 gene has been identified to be 1233 nucleotides long and to code for a polypeptide of 411 amino acids with a calculated molecular weight of 45,358. The amino acid sequence encoded in CPA1 is homologous to the recently determined sequence of the small subunit of Escherichia coli carbamyl phosphate synthetase (Piette, J., Nyunoya, H., Lusty, C.J., Cunin, R., Weyens, G., Crabeel, M., Charlier, D., Glandsdorff, N., and Pierard, A. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 4134-4138) over the entire length of the polypeptide chain. Comparison of the amino acid sequences of the small subunits of yeast and E. coli carbamyl phosphate synthetases to the sequences of Component II of anthranilate and p-aminobenzoate synthases suggests that these amidotransferases are evolutionarily related. The most highly conserved region of the yeast and E. coli enzymes includes a cysteine residue previously found to be at the active site of Pseudomonas putida anthranilate synthase Component II (Kawamura, M., Keim, P.S., Goto, Y., Zalkin, H., and Heinrikson, R.L. (1978) J. Biol. Chem. 253, 4659-4668). Based on the observed homologies in the primary sequences of the other amidotransferases examined, we propose a 13-amino acid long sequence to be part of the catalytic domain of this class of enzymes.     

A dominant negative G alpha s mutant is rescued by secondary mutation of the alpha chain amino terminus.

The Gs protein alpha subunit, alpha s, stimulates the activity of adenylyl cyclase. The sequence 223Asp-Val-Gly-Gly-Gln227 in the alpha s polypeptide is predicted to interact with the gamma-phosphate of GTP and mediate the conformational change involved in alpha s activation. Mutation of the alpha s polypeptide within this region at Gly225----Thr had two demonstrative phenotypic effects when expressed in COS-1 cells: the mutant alpha s chain was ineffective in activating adenylyl cyclase and inhibited in a concentration-dependent manner the beta-adrenergic receptor stimulation of cAMP synthesis. Thus, the Gly225----Thr mutation alters the ability of GTP to activate the alpha s chain and when overexpressed the mutant polypeptide exerts a dominant negative phenotype. Mutation at the amino terminus which creates a constitutively active alpha s rescued the inhibited state of the Gly225----Thr mutant when both mutations were encoded in the same polypeptide. This finding defines the amino terminus as a functional regulatory domain controlling the properties of the GTP/GDP binding site of G protein alpha subunit polypeptide chains.     

The yeast ATP synthase subunit 4: structure and function

The structure of ATP synthase subunit 4 was determined by using the oligonucleotide probe procedure. This subunit is the fourth polypeptide of the complex when classifying subunits in order of decreasing molecular mass. Its relative molecular mass is 25 kDa. The ATP4 gene was isolated and sequenced. The nucleotide sequence predicts that subunit 4 is probably derived from a precursor protein 244 amino acids long. Mature subunit 4 contains 209 amino acid residues and the predicted molecular mass is 23250 kDa. Subunit 4 shows homology with the b-subunit of Escherichia coli ATP synthase and the b-subunit of beef heart mitochondrial ATP synthase. By using homologous transformation, a mutant lacking wild subunit 4 was constructed. This mutant is devoid of oxidative phosphorylation and F1 is loosely bound to the membrane. Our data are in favor of a structural relationship between subunit 4 and the mitochondrially-translated subunit 6 during biogenesis of F0.     

Nucleotide sequence of ATPase subunit 6 gene of maize mitochondria

The ATPase subunit 6, located in the inner mitochondrial membrane, is encoded by mitochondrial genomes in animals and fungi. We have isolated and characterized a mitochondrial gene, designated atp 6, that encodes the subunit 6 polypeptide of Zea mays. Nucleotide and predicted amino acid sequence comparisons have revealed a homology of 44.6 and 33.2% with the yeast ATPase subunit 6 gene and polypeptide, respectively. The predicted protein in maize contains 291 amino acids with a molecular weight of 31,721. Hydropathy profiles generated for the maize and yeast polypeptides are very similar and contain large hydrophobic domains, characteristic of membrane bound proteins. RNA transfer blot analysis indicates that atp 6 is actively transcribed. Interestingly, 122 base pairs of nucleotide sequence interior to atp 6 have extensive homology with the 5′ end of the cytochrome oxidase subunit II gene of maize mitochondria, suggesting recombination between the two genes.     

Genetic organization of the mau gene cluster in Methylobacterium extorquens AM1: complete nucleotide sequence and generation and characteristics of mau mutants.

The nucleotide sequence of the methylamine utilization (mau) gene region from Methylobacterium extorquens AM1 was determined. Open reading frames for 11 genes (mauFBEDACJGLMN) were found, all transcribed in the same orientation. The mauB, mauA, and mauC genes encode the periplasmic methylamine dehydrogenase (MADH) large and small subunit polypeptides and amicyanin, respectively. The products of mauD, mauG, mauL, and mauM were also predicted to be periplasmic. The products of mauF, mauE, and mauN were predicted to be membrane associated. The mauJ product is the only polypeptide encoded by the mau gene cluster which is predicted to be cytoplasmic. Computer analysis showed that the MauG polypeptide contains two putative heme binding sites and that the MauM and MauN polypeptides have four and two FeS cluster signatures, respectively. Mutants generated by insertions in mauF, mauB, mauE, mauD, mauA, mauG, and mauL were not able to grow on methylamine or any other primary amine as carbon sources, while a mutant generated from an insertion in mauC was not able to utilize methylamine as a source of carbon but utilized C2 to C4 n-alkylamines as carbon sources. Insertion mutations in mauJ, mauM, and mauN did not impair the ability of the mutants to utilize primary n-alkylamines as carbon sources. All mau mutants were able to utilize methylamine as a nitrogen source, implying the existence of an alternative (methyl)amine oxidation system, and a low activity of N-methylglutamate dehydrogenase was detected. The mauD, mauE, and mauF mutants were found to lack the MADH small subunit polypeptide and have a decreased amount of the MADH large subunit polypeptide. In the mauG and mauL mutants, the MADH large and small subunit polypeptides were present at wild-type levels, although the MADHs in these strains were not functional. In addition, MauG has sequence similarity to cytochrome c peroxidase from Pseudomonas sp. The mauA, mauD, and mauE genes from Paracoccus denitrificans and the mauD and mauG genes from Methylophilus methylotrophus W3A1 were able to complement corresponding mutants of M. extorquens AM1, confirming their functional equivalence. Comparison of amino acid sequences of polypeptides encoded by mau genes from M. extorquens AM1, P. denitrificans, and Thiobacillus versutus shows that they have considerable similarity.     

Influenza C virus hemagglutinin: comparison with influenza A and B virus hemagglutinins

The complete nucleotide sequence of the influenza C/California/78 virus RNA 4 was obtained by using cloned cDNA derived from the RNA segment. This gene is 2,071 nucleotides long and can code for a polypeptide of 654 amino acids. Although there are no convincing sequence homologies between RNA 4 and the hemagglutinin genes of influenza A and B viruses, we suggest, on the basis of structural features, that RNA 4 of the influenza C virus codes for the hemagglutinin. The structural features which are common to the hemagglutinins of influenza A, B, and C viruses include (i) a hydrophobic signal peptide, (ii) an arginine cleavage site between the hemagglutinin 1 and 2 subunits, (iii) hydrophobic regions at the amino and carboxyl termini of the hemagglutinin 2 subunit, and (iv) several conserved cysteine residues. Additional evidence that RNA 4 of influenza C virus codes for the hemagglutinin is that the tripeptide Ile-Phe-Gly, known to be present at the amino terminus of the hemagglutinin 2 subunit of influenza C virus, is encoded by RNA 4 at a point immediately adjacent to the presumptive arginine cleavage site. The lack of primary sequence homology between the influenza C virus hemagglutinin and the influenza A or B virus hemagglutinins, which all have similar functions, might be attributed to convergent rather than divergent evolution. However, the structural similarities among the influenza A, B, and C virus hemagglutinins strongly suggest that the three hemagglutinin genes have diverged from a common precursor.     

MAS5, a yeast homolog of DnaJ involved in mitochondrial protein import.

The nuclear mas5 mutation causes temperature-sensitive growth and defects in mitochondrial protein import at the nonpermissive temperature in the yeast Saccharomyces cerevisiae. The MAS5 gene was isolated by complementation of the mutant phenotypes, and integrative transformation demonstrated that the complementing fragment encoded the authentic MAS5 gene. The deduced protein sequence of the cloned gene revealed a polypeptide of 410 amino acids which is homologous to Escherichia coli DnaJ and the yeast DnaJ log SCJ1. Northern (RNA blot) analysis revealed that MAS5 is a heat shock gene whose expression increases moderately at elevated temperatures. Cells with a deletion mutation in MAS5 grew slowly at 23 degrees C and were inviable at 37 degrees C, demonstrating that MAS5 is essential for growth at increased temperatures. The deletion mutant also displayed a modest import defect at 23 degrees C and a substantial import defect at 37 degrees C. These results indicate a role for a DnaJ cognate protein in mitochondrial protein import.