Nucleotide sequence analysis of alpha-amylase and thiol protease genes that are hormonally regulated in barley aleurone cells

Structural organization and functional divergence of high isoelectric point α-amylase genes in bread wheat (Triticum aestivum L.) and barley (Hordeum vulgare L.)

BACKGROUND

High isoelectric point α-amylase genes (Amy1) play major roles during cereal seed germination, and are associated with unacceptable high residual α-amylase activities in ripe wheat grains. However, in wheat and barley, due to extremely high homology of duplicated copies, and large and complex genome background, the knowledge on this multigene family is limited.

RESULTS

In the present work, we identified a total of 41 Amy1 genes among 13 investigated grasses. By using genomic resources and experimental validation, the exact copy numbers and chromosomal locations in wheat and barley were determined. Phylogenetic and syntenic analyses revealed tandem gene duplication and chromosomal rearrangement leading to separation of Amy1 into two distinct loci, Amy1θ and Amy1λ. The divergence of Amy1λ from Amy1θ was driven by adaptive selection pressures performed on two amino acids, Arg97 and Asn233 (P > 0.95*). The predicted protein structural alteration caused by substitution of Asp233Asn in the conserved starch binding surface site, and significantly expressional differentiation during seed germination and grain development provided evidence of functional divergence between Amy1θ and Amy1λ genes. We screened out candidate copies (TaAmy1-A1/A2 and TaAmy1-D1) associated with high residual α-amylase activities in ripe grains. Furthermore, we proposed an evolutionary model for expansion dynamics of Amy1 genes.

CONCLUSIONS

Our study provides comprehensive analyses of the Amy1 multigene family, and defines the fixation of two spatially structural Amy1 loci in wheat and barley. Potential functional divergence between them is reflected by their sequence features and expressional patterns, and driven by gene duplication, chromosome rearrangement and natural selections during gene family evolution. Furthermore, the discrimination of differentially effective copies during seed germination and/or grain development will provide guidance to manipulation of α-amylase activity in wheat and barley breeding for better yield and processing properties.

Comparisons of Copy Number, Genomic Structure, and Conserved Motifs for α-Amylase Genes from Barley, Rice, and Wheat

Barley is an important crop for the production of malt and beer. However, crops such as rice and wheat are rarely used for malting. α-amylase is the key enzyme that degrades starch during malting. In this study, we compared the genomic properties, gene copies, and conserved promoter motifs of α-amylase genes in barley, rice, and wheat. In all three crops, α-amylase consists of four subfamilies designated amy1, amy2, amy3, and amy4. In wheat and barley, members of amy1 and amy2 genes are localized on chromosomes 6 and 7, respectively. In rice, members of amy1 genes are found on chromosomes 1 and 2, and amy2 genes on chromosome 6. The barley genome has six amy1 members and three amy2 members. The wheat B genome contains four amy1 members and three amy2 members, while the rice genome has three amy1 members and one amy2 member. The B genome has mostly amy1 and amy2 members among the three wheat genomes. Amy1 promoters from all three crop genomes contain a GA-responsive complex consisting of a GA-responsive element (CAATAAA), pyrimidine box (CCTTTT) and TATCCAT/C box. This study has shown that amy1 and amy2 from both wheat and barley have similar genomic properties, including exon/intron structures and GA-responsive elements on promoters, but these differ in rice. Like barley, wheat should have sufficient amy activity to degrade starch completely during malting. Other factors, such as high protein with haze issues and the lack of husk causing Lauting difficulty, may limit the use of wheat for brewing.

Production of barley endoprotease B2 in Pichia pastoris and its proteolytic activity against native and recombinant hordeins

Barley (Hordeum vulgare L.) cysteine proteases are of fundamental biological importance during germination but may also have a large potential as commercial enzyme. Barley cysteine endoprotease B2 (HvEPB2) was expressed in Pichia pastoris from a pPICZαA based construct encoding a HvEPB2 C-terminal truncated version (HvEPB2ΔC) and a proteolytic resistant His6 tag. Maximum yield was obtained after 4 days of induction. Recombinant HvEPB2ΔC (r-HvEPB2ΔC) was purified using a single step of Ni(2+)-affinity chromatography. Purified protein was evaluated by SDS-PAGE, Western blotting and activity assays. A purification yield of 4.26 mg r-HvEPB2ΔC per L supernatant was obtained. r-HvEPB2ΔC follows first order kinetics (Km=12.37 μM) for the substrate Z-Phe-Arg-pNA and the activity was significantly inhibited by the cysteine protease specific inhibitors E64 and leupeptin. The temperature optimum for r-HvEPB2ΔC was 60°C, thermal stability T50 value was 44°C and the pH optimum was 4.5. r-HvEPB2ΔC was incubated with native purified barley seed storage proteins for up to 48 h. After 12h, r-HvEPB2ΔC efficiently reduced the C and D hordeins almost completely, as evaluated by SDS-PAGE. The intensities of the B and γ hordein bands decreased continuously over the 48 h. No degradation occurred in the presence of E64. Recombinant hordeins (B1, B3 and γ1) were expressed in Escherichia coli. After 2h of incubation with r-HvEPB2ΔC, an almost complete degradation of γ1 and partial digests of hordein B1 and B3 were observed.

Tomato polyphenol oxidase B is spatially and temporally regulated during development and in response to ethylene

Plant polyphenol oxidases (PPOs) are ubiquitous plastid-localized enzymes. A precise analysis of PPO function in plants has been complicated by the presence of several family members with immunological cross reactivity. Previously we reported the isolation of genomic clones coding for the seven members of the tomato (Solanum lycopersicum) PPO family (A, A', B, C, D, E, and F). Here we report the complex spatial and temporal expression of one of the members, PPO B. The PPO B promoter was sequenced and subjected to homology analysis. Sequence similarities were found to nucleotide sequences of genes encoding enzymes/proteins active in the following systems: phenylpropanoid biosynthesis, signal transduction and responsiveness to hormones and stresses, fruit and seed proteins/enzymes, and photosynthesis. Chimeric gene fusions were constructed linking PPO B 5' flanking regions to the reporter gene, b-glucuronidase (GUS). The resultant transgenic plants were histochemically analyzed for GUS activity in various vegetative and reproductive tissues, and evaluated for PPO B responsiveness to ethylene induction. It was shown that PPO B expression was tissue specific, developmentally regulated, ethylene induced, and localized predominantly to mitotic or apoptotic tissues.

Development-dependent changes in the tight DNA-protein complexes of barley on chromosome and gene level

BACKGROUND

The tightly bound to DNA proteins (TBPs) is a protein group that remains attached to DNA with covalent or non-covalent bonds after its deproteinisation. The functional role of this group is as yet not completely understood. The main goal of this study was to evaluate tissue specific changes in the TBP distribution in barley genes and chromosomes in different phases of shoot and seed development. We have: 1. investigated the TBP distribution along Amy32b and Bmy1 genes encoding low pI alpha-amylase A and endosperm specific beta-amylase correspondingly using oligonucleotide DNA arrays; 2. characterized the polypeptide spectrum of TBP and proteins with affinity to TBP-associated DNA; 3. localized the distribution of DNA complexes with TBP (TBP-DNA) on barley 1H and 7H chromosomes using mapped markers; 4. compared the chromosomal distribution of TBP-DNA complexes to the distribution of the nuclear matrix attachment sites.

RESULTS

In the Amy32b gene transition from watery ripe to the milky ripeness stage of seed development was followed by the decrease of TBP binding along the whole gene, especially in the promoter region and intron II. Expression of the Bmy1 gene coupled to ripening was followed by release of the exon III and intron III sequences from complexes with TBPs. Marker analysis revealed changes in the association of chromosome 1H and 7H sites with TBPs between first leaf and coleoptile and at Zadoks 07 and Zadoks 10 stages of barley shoot development. Tight DNA-protein complexes of the nuclear matrix and those detected by NPC-chromatography were revealed as also involved in tissue- and development-dependent transitions, however, in sites different from TBP-DNA interactions. The spectrum of TBPs appeared to be organ and developmental-stage specific. Development of the first leaf and root system (from Zadoks 07 to Zadoks 10 stage) was shown as followed by a drastic increase in the TBP number in contrast to coleoptile, where the TBPs spectrum became poor during senescence. It was demonstrated that a nuclear protein of low molecular weight similar to the described TBPs possessed a high affinity to the DNA involved in TBP-DNA complexes.

CONCLUSION

Plant development is followed by redistribution of TBP along individual genes and chromosomes.

Construction and characterization of two BAC libraries from Brachypodium distachyon, a new model for grass genomics

Brachypodium is well suited as a model system for temperate grasses because of its compact genome and a range of biological features. In an effort to develop resources for genome research in this emerging model species, we constructed 2 bacterial artificial chromosome (BAC) libraries from an inbred diploid Brachypodium distachyon line, Bd21, using restriction enzymes HindIII and BamHI. A total of 73,728 clones (36,864 per BAC library) were picked and arrayed in 192,384-well plates. The average insert size for the BamHI and HindIII libraries is estimated to be 100 and 105 kb, respectively, and inserts of chloroplast origin account for 4.4% and 2.4%, respectively. The libraries individually represent 9.4- and 9.9-fold haploid genome equivalents with combined 19.3-fold genome coverage, based on a genome size of 355 Mb reported for the diploid Brachypodium, implying a 99.99% probability that any given specific sequence will be present in each library. Hybridization of the libraries with 8 starch biosynthesis genes was used to empirically evaluate this theoretical genome coverage; the frequency at which these genes were present in the library clones gave an estimated coverage of 11.6- and 19.6-fold genome equivalents. To obtain a first view of the sequence composition of the Brachypodium genome, 2185 BAC end sequences (BES) representing 1.3 Mb of random genomic sequence were compared with the NCBI GenBank database and the GIRI repeat database. Using a cutoff expectation value of E<10-10, only 3.3% of the BESs showed similarity to repetitive sequences in the existing database, whereas 40.0% had matches to the sequences in the EST database, suggesting that a considerable portion of the Brachypodium genome is likely transcribed. When the BESs were compared with individual EST databases, more matches hit wheat than maize, although their EST collections are of a similar size, further supporting the close relationship between Brachypodium and the Triticeae. Moreover, 122 BESs have significant matches to wheat ESTs mapped to individual chromosome bin positions. These BACs represent colinear regions containing the mapped wheat ESTs and would be useful in identifying additional markers for specific wheat chromosome regions.

Complete, precise, and innocuous loss of multiple introns in the currently intronless, active cathepsin L-like genes, and inference from this event

Retrotransposition typically generates pseudogenes. Here we demonstrate a different fate of the retro-processed genes through a novel mechanism in which the retro-processed genes still maintain their sequence intactness and the original functions. We show that the shrimp cathepsin L (CatL) gene MeCatL has lost all of its five introns. Also, ProEPB, the ancestor of the CatL-like barley EPBs and rice REP1, has lost all of its three introns. The multiple introns in a gene might have been eliminated simultaneously and precisely at the original locus for the CatL-like genes of shrimp, barley, rice, Drosophila, and Theileria. We reason that retrotransposition is not responsible for the generation of a processed active intronless (PAI) gene when the gene product retains its sequence intactness and its original function. We propose that double-strand-break repair (DSBR) machinery might play a role in cDNA-mediated homologous recombination (cDMHR) that causes the loss of introns. The cDMHR/DSBR pathway is probably a fundamental mechanism for intron loss in PAI genes and in some asymmetric-intron genes.

Coding region single nucleotide polymorphism in the barley low-pI, alpha-amylase gene Amy32b

Barley alpha-amylase variability influences the quality of barley grain in the brewing, feed and food industries. alpha-Amylase proteins are encoded by multigene families in cereals, and this study focused on the barley Amy32b gene. We identified coding region single nucleotide polymorphism (cSNP) and insertion/deletion variation in DNA sequences, which resulted in amino acid substitution and stop codon formation, respectively. The substitution affected the beta1 strand in domain C, whereas the stop codon removed the beta5 strand. Possible effects of these changes on the protein are discussed. A cSNP in the coding region of the Amy32b gene was used as a specific marker to map Amy32b loci on chromosome 7H.

Modification of senescence in ryegrass transformed with IPT under the control of a monocot senescence-enhanced promoter

We report here the genetic modification of ryegrass senescence. Embryogenic cell suspensions of Lolium multiflorum were transformed by microprojectile bombardment with plasmid constructs containing 1.98 kb of the 5' flanking sequence of SEE1 (a maize cysteine protease gene showing enhanced expression during senescence) fused either to the Agrobacterium tumefaciens cytokinin biosynthesis gene IPT (designated PSEE1::IPT) or to the beta-glucuronidase reporter gene UIDA (PSEE1::UIDA). Plants were regenerated under selection for the HPH hygromycin resistance gene in the vector. PSEE1::UIDA transformants confirmed that the SEE1 flanking sequence functioned as a senescence-enhanced promoter in ryegrass. The IPT transgene was detected in 28 regenerants (PSEE1::IPT) from five independent transformation events. PSEE1::IPT leaves displayed a stay-green phenotype. Some PSEE1::IPT lines developed spontaneous lesions.

A role for the DOF transcription factor BPBF in the regulation of gibberellin-responsive genes in barley aleurone

Functional analyses of a number of hydrolase gene promoters, induced by gibberellin (GA) in aleurone cells following germination, have identified a GA-responsive complex as a tripartite element containing a pyrimidine box motif 5'-CCTTTT-3'. We describe here that BPBF, a barley (Hordeum vulgare) transcription factor of the DOF (DNA-Binding with One Finger) class, previously shown to be an activator of reserve protein encoding genes during development, also has a role in the control of hydrolase genes following seed germination. Northern-blot, reverse transcriptase-polymerase chain reaction, and in situ hybridization analyses evidenced that the transcripts of the BPBF-encoding gene (Pbf), besides being present during endosperm development, are also expressed in aleurone cells of germinated seeds where they are induced by GA, an effect counteracted by abscisic acid. Electrophoretic mobility shift assays have shown that the BPBF protein binds specifically to the pyrimidine box motif in vitro within the different sequence contexts that naturally occur in the promoters of genes encoding a cathepsin B-like protease (Al21) and a low-isoelectric point alpha-amylase (Amy2/32b), both induced in the aleurone layers in response to GA. In transient expression experiments, BPBF repressed transcription of the Al21 promoter in GA-treated barley aleurone layers and reverted the GAMYB-mediated activation of this protease promoter.

T-DNA integration into the barley genome from single and double cassette vectors

Patterns and sites of T-DNA integrations into the barley genome from single and double cassette vectors are of interest for the identification of cultivars with value added properties as well as for the production of selection marker-free transgenic lines that can be retransformed. T-DNA/Plant DNA junctions were obtained by capturing a single-stranded DNA with a biotinylated primer annealing to the vector adjacent to the border and an adaptor ligated to a restriction site overhang in the flanking barley DNA. The captured junction was converted into a double strand and sequenced. Fifty left and right border junctions from plants transgenic for one of five human genes were analyzed. Primers of 15-30 nucleotides designed from the genomic DNA at the insertion site can PCR amplify fragments that identify unequivocally any transformant. Adjacent transgene insertions with single cassette vectors were always in tandem direct repeat configuration. With regard to T-DNA integration the patterns were comparable to the variations found in dicotyledonous plants. Twelve of the 46 integrations characterized by blast searches were within different regions of the BARE-1 retrotransposon element occurring with a frequency of 2 x 10(5) copies in the barley genome. The use of border junctions to identify number of copies and loci of integrates in transformants is discussed.

Specific inhibition of barley alpha-amylase 2 by barley alpha-amylase/subtilisin inhibitor depends on charge interactions and can be conferred to isozyme 1 by mutation

alpha-Amylase 2 (AMY2) and alpha-amylase/subtilisin inhibitor (BASI) from barley bind with Ki = 0.22 nM. AMY2 is a (beta/alpha)8-barrel enzyme and the segment Leu116-Phe143 in domain B (Val89-Ile152), protruding at beta-strand 3 of the (beta/alpha)8-barrel, was shown using isozyme hybrids to be crucial for the specificity of the inhibitor for AMY2. In the AMY2-BASI crystal structure [F. Vallée, A. Kadziola, Y. Bourne, M. Juy, K. W. Rodenburg, B. Svensson & R. Haser (1998) Structure 6, 649-659] Arg128AMY2 forms a hydrogen bond with Ser77BASI, while Asp142AMY2 makes a salt-bridge with Lys140BASI. These two enzyme residues are substituted by glutamine and asparagine, respectively, to assess their contribution in binding of the inhibitor. These mutations were performed in the well-expressed, inhibitor-sensitive hybrid barley alpha-amylase 1 (AMY1)-(1-90)/AMY2-(90-403) with Ki = 0.33 nM, because of poor production of AMY2 in yeast. In addition Arg128, only found in AMY2, was introduced into an AMY1 context by the mutation T129R/K130P in the inhibitor-insensitive hybrid AMY1-(1-161)/AMY2-(161-403). The binding energy was reduced by 2.7-3.0 kcal.mol-1 as determined from Ki after the mutations R128Q and D142N. This corresponds to loss of a charged interaction between the protein molecules. In contrast, sensitivity to the inhibitor was gained (Ki = 7 microM) by the mutation T129R/K130P in the insensitive isozyme hybrid. Charge screening raised Ki 14-20-fold for this latter mutant, AMY2, and the sensitive isozyme hybrid, but only twofold for the R128Q and D142N mutants. Thus electrostatic stabilization was effectively introduced and lost in the different mutant enzyme-inhibitor complexes and rational engineering using an inhibitor recognition motif to confer binding to the inhibitor mimicking the natural AMY2-BASI complex.

Sequencing, expression pattern and RFLP mapping of a senescence-enhanced cDNA from Zea mays with high homology to oryzain gamma and aleurain

Sequence analysis of a 1.4 kb clone from a cDNA library of senescing Zea mays leaves reveals an open reading frame for a 360 amino acid protein. Both the DNA and deduced amino acid sequences are highly homologous to the cysteine proteinases oryzain gamma and aleurain. Northern analysis demonstrates that the corresponding RNA level increases during natural leaf senescence, seedling germination and in chilling of tolerant maize lines, but decreases in a sensitive line. The mRNA level also decreases in regreening leaves, in dark-induced senescence and in nutrient or water stress. Southern and RFLP analysis provide evidence that the gene has two copies, on chromosomes 2 and 7.

Leaf senescence in Brassica napus: cloning of senescence related genes by subtractive hybridisation

A subtractive hybridisation technique was developed to clone cDNAs representing genes that showed enhanced expression during leaf senescence in Brassica napus. A number of different genes were identified that, when analysed by northern hybridisation, showed different patterns of expression during leaf development but were all expressed at increased levels during senescence. Sequence analysis of these cDNAs showed that several types of genes were found including two different proteases, glutamine synthetase, ATP sulphurylase, catalase, metallothionein, ferritin and an antifungal protein. The possible roles of these gene products in the senescence process are discussed.

Localization and interaction of the cis-acting elements for abscisic acid, VIVIPAROUS1, and light activation of the C1 gene of maize

The C1 regulatory gene of the maize anthocyanin pathway is regulated by a combination of developmental and environmental signals that include the Viviparous1 (Vp1) gene, abscisic acid (ABA), and light. Using protoplast electroporation and particle bombardment assays, we have defined c/s-acting elements that are necessary and sufficient for the activation of C1 by ABA, VP1, and light, respectively. The sequence from positions -142 to -132 (CGTCCATGCAT) is essential for VP1 activation, whereas a larger overlapping element from -147 to -132 (CGTGTCGTCCATGCAT) is necessary and sufficient for activation by ABA. A separate light (blue and red)-responsive c/s element is located between positions -116 and -59. Light interacts synergistically with the ABA and VP1 responses in transient expression assays, suggesting that combinatorial interaction between modules plays a role in integrating these signals in the developing seed.

The BARE-1 retrotransposon is transcribed in barley from an LTR promoter active in transient assays

The BARE-1 retrotransposon occurs in more than 10(4) copies in the barley genome. The element is bounded by long terminal repeats (LTRs, 1829 bp) containing motifs typical of retrotransposon promoters. These, the presence of predicted priming sites for reverse transcription, and the high conservation for all key functional domains of the coding region suggest that copies within the genome could be active retrotransposons. In view of this, we looked for transcription of BARE-1 within barley tissues and examined the promoter function of the BARE-1 LTR. We demonstrate here that BARE-1-like elements are transcribed in barley tissues, and that the transcripts begin within the BARE-1 LTR downstream of TATA boxes. The LTR can drive expression of reporter genes in transiently transformed barley protoplasts. This is dependent on the presence of a TATA box functional in planta as well. Furthermore, we identify regions within the LTR responsible for expression within protoplasts by deletion analyses of LTR-luc constructs. Similarities between promoter regulatory motifs and regions of the LTR were identified by comparisons to sequence libraries. The activity of the LTR as a promoter, combined with the abundance of BARE-1 in the genome, suggests that BARE-1 may retain the potential for propagation in the barley genome.

Alternative polyadenylation generates three low-pI alpha-amylase mRNAs with differential expression in barley

Specific low-pI alpha-amylase genes from barley (Hordeum vulgare L.) produced alternative mRNAs with a 17-base 3' extension (extension 1) or a 17-base extension beyond this (extension 2). The extended mRNAs do not arise from splicing of downstream sequences, and not all low-pI genes contain the extended sequences. All three mRNAs occur in aleurones and shoots, while extension 2 is missing from scutella. Also, the unextended mRNAs predominate in total mRNA, but the extended mRNAs predominate in membrane-bound polysomes. The extended sequences do not occur in previously characterized alpha-amylases, but 16 of 18 bases, mainly in extension 1, are identical with a sequence in the 3'-UTR of PAPI, a putative inhibitor of alpha-amylase. These observations suggest that the extended sequences could play a functional role in alpha-amylase expression.

Models for the action of barley alpha-amylase isozymes on linear substrates

The formation of maltodextrins, G1 to G12, during the hydrolysis of amylose by alpha-amylases 1 and 2 from barley malt was followed by HPLC. Similar, but not identical, distributions of products were obtained with the two alpha-amylase components. Maltose, G6, and G7 were major products, but G7 was degraded as hydrolysis proceeded. alpha-Amylase 1 produced more G1 and G3 than did alpha-amylase 2 at all stages of hydrolysis. Products formed during the hydrolysis of G9, G10, G11, and G12 by the two alpha-amylases were also determined. A different spectrum of products was observed with each substrate and small differences were observed in the action pattern of the two alpha-amylases, e.g., G3 and G7 were the major products formed during the hydrolysis of G10 by alpha-amylase 1, whereas G2 and G8 were the major products formed by alpha-amylase 2 on the same substrate. These results were used to develop a model of the active site of barley malt alpha-amylases. This site contains ten contiguous subsites with the catalytic site situated between subsites 7 and 8. The model can be used to predict hydrolysis patterns of amylose and maltodextrins by cereal alpha-amylases.

The cis-acting gibberellin response complex in high pI alpha-amylase gene promoters. Requirement of a coupling element for high-level transcription

In cereal alpha-amylase gene promoters the cis-acting gibberellin response element (GARE) is required for increased transcription in the presence of gibberellin. In low-isoelectric point (pI) alpha-amylase gene promoters a second type of cis element, termed a coupling element, must also be present in a specific position near the GARE; otherwise, the level of transcription in the presence of gibberellin is only a few percent of maximum. The coupling element may help determine where and when in development high-level, hormonally regulated transcription will occur. Such coupling elements have not yet been shown to be necessary for high-level transcription from high-pI alpha-amylase gene promoters. Here we use quantitative transient expression assays to show that a high-pI promoter truncated to -300 is a weak promoter due to the absence of a functional coupling element in the vicinity of the GARE. Gibberellin-induced transcription increases substantially when coupling element function is provided, either by appending upstream regions normally attached to the promoter or by inserting a defined coupling element from a low-pI promoter. Thus, in a second type of gibberellin-regulated promoter coupling element function was found to be crucial for hormone regulation to result in high-level transcription.

Gibberellin treatment stimulates nuclear factor binding to the gibberellin response complex in a barley alpha-amylase promoter

The promoters of a majority of cereal alpha-amylase genes contain three highly conserved sequences (gibberellin response element, box I, and pyrimidine box). Recent studies have demonstrated the functional importance of four regions that either coincide with or are immediately proximal to these three conserved elements as well as an upstream Opaque-2 binding sequence. In this study, we describe the characterization of nuclear protein factors from barley aleurone layers whose binding activity toward gibberellin response complex sequences from the barley low-pl alpha-amylase gene (Amy32b) promoter is stimulated by gibberellin A3 (GA3) treatment. Barley proteins isolated from crude nuclear extracts prepared from aleurone layers incubated with or without GA3 were fractionated by anion exchange fast protein liquid chromatography and studied using band shift assays, sequence-specific competitions, and DNase I footprinting. A GA3-dependent binding activity eluting at 210 mM KCl was shown to bind specifically to the gibberellin response element and the closely associated box I. DNase I footprinting with the proteins in this fraction indicated interactions with sequences in the gibberellin response element and box I. A second DNA binding activity eluting at 310 mM KCl was present constitutively in extracts prepared from tissues incubated both in the absence and in the presence of hormone. Proteins in this fraction were able to bind to many DNA sequences and, in general, were largely nonspecific. DNase I footprinting with the proteins in this fraction indicated a large area of protection with a single unoccupied region located at the 3' end of box I. The possible function of such an activity in hormone regulation of the alpha-amylase genes is discussed.

Analysis of the gibberellin-responsive promoter of a cathepsin B-like gene from wheat

A wheat gene (A121) encoding a protein with sequence similarity to mammalian cathepsin B is regulated by gibberellic acid (GA) in aleurone layers of germinating grains. To analyse the mechanism of A121 regulation, its promoter was fused to the beta-glucuronidase reporter gene (GUS) and introduced by micro-projectile bombardment into aleurone layers of oat. With 2.3 kb of promoter sequence, the GUS expression was enhanced by GA treatment. This effect was reversed by abscisic acid (ABA). This result showed for A121, like the alpha-amylase genes, that the regulation by GA and ABA was at the level of transcription. The GA responsiveness of the promoter was retained with as little as 276 bp of promoter sequence. Sequence comparison with a GA responsive promoter of an alpha-amylase gene identified the conserved element GCAACGGCAACGATGG which is required intact for full expression of both promoters. However, there was no identifiable similarity in the cathepsin-like promoter with the GA-responsive element of alpha-amylase promoters with the consensus sequence TAACAAA, suggesting that GA affects more than one mechanism of transcriptional control.

Isolation of putative cysteine protease genes of Ostertagia ostertagi

Recombinant phage containing putative Ostertagia ostertagi cysteine protease genes have been isolated from a lambda EMBL-3:genomic DNA library using a Haemonchus contortus cathepsin B-like cysteine protease cDNA as hybridization probe. Restriction enzyme maps of the phages suggest that they identify at least 3 genes, 2 of which appear to be linked in tandem. The complete nucleotide sequence of one gene, CP-1, was determined. The CP-1 gene appears to be organized into 12 exons than span 4.5 kb of DNA. The number and sizes of the exons are essentially identical to those in the H. contortus AC-2 cysteine protease gene. Partial nucleotide sequences obtained for a second O. ostertagi gene, CP-3, revealed a similar organization for exons 8-12 in this gene. Like other cathepsin B-like cysteine proteases, CP-1 appears to be synthesized initially as a preproprotein that is proteolytically processed to its mature form. The amino acid identity between the presumptive CP-1 and CP-3 proteins is 66%, which is similar to the level of homology between the presumed mature protein regions of CP-1 and AC-2. Amino acid identity between CP-1 and AC-2 is greatest in the mature protein region and lowest in the signal sequence and propeptide regions. The CP-3 protein appears to be most closely related to the H. contortus AC-5 protein. CP-1 and CP-3 display significantly greater homology to H. contortus cysteine proteases than they do to human cathepsin B or the Sm31 cysteine protease of Schistosoma mansoni (about 40% identity with each).

Classification and evolution of alpha-amylase genes in plants

The DNA sequences for 17 plant genes for alpha-amylase (EC 3.2.1.1) were analyzed to determine their phylogenetic relationship. A phylogeny for these genes was obtained using two separate approaches, one based on molecular clock assumptions and the other based on a comparison of sequence polymorphisms (i.e., small and localized insertions) in the alpha-amylase genes. These polymorphisms are called "alpha-amylase signatures" because they are diagnostic of the gene subfamily to which a particular alpha-amylase gene belongs. Results indicate that the cereal alpha-amylase genes fall into two major classes: AmyA and AmyB. The AmyA class is subdivided into the Amy1 and Amy2 subfamilies previously used to classify alpha-amylase genes in barley and wheat. The AmyB class includes the Amy3 subfamily to which most of the alpha-amylase genes of rice belong. Using polymerase chain reaction and oligonucleotide primers that flank one of the two signature regions, we show that the AmyA and AmyB gene classes are present in approximately equal amounts in all grass species examined except barley. The AmyB (Amy3 subfamily) genes in the latter case are comparatively underrepresented. Additional evidence suggests that the AmyA genes appeared recently and may be confined to the grass family.

Structure of the genes encoding Hordeum vulgare (1----3,1----4)-beta-glucanase isoenzymes I and II and functional analysis of their promoters in barley aleurone protoplasts

Barley (1----3,1----4)-beta-glucanase isoenzyme II is synthesized in the aleurone cells during germination and secreted into the endosperm for hydrolysis of the cell walls. Its synthesis is stimulated by gibberellic acid (GA3) and repressed by abscisic acid. The gene for isoenzyme I is expressed in the aleurone, scutellum and prominently in young leaves. Close functional relatedness between the two enzymes is attested by 92% identity at the level of the amino acid sequence. The structural genes for the two enzymes each contain a large intron of 2505 bp and 2952 bp, respectively, in the codon for amino acid 25 of the 28-residue signal peptide. During evolution, homologous regions of the two introns have changed position and orientation. Furthermore, a large palindromic sequence of 327 bp in the 5' end of the intron is present only in the gene for isoenzyme II. In transient expression assays using barley aleurone protoplasts and chloramphenicol acetyl transferase as reporter the promoter of the isoenzyme I gene showed no response to GA3. However, removal of a unique 151 bp region extending from positions -402 to -552 upstream of the TATA box permitted low levels of GA3-induced expression of the reporter gene, suggesting a silencer function for this domain. High levels of GA3-responsive expression were obtained in aleurone protoplasts using the promoter of the gene encoding isoenzyme II. Truncation of this promoter revealed that sequences located within 253 bp upstream from the TATA box are sufficient to direct GA3-stimulated expression. Using the homologous barley aleurone protoplast transfection assay, it was possible to reproduce the in vivo expression characteristics of the genes for the barley (1----3,1----4)-beta-glucanase isoenzymes I and II with reporter gene constructs.

Suppression of alpha-amylase gene expression by antisense oligodeoxynucleotide in barley cultured aleurone layers

Antisense oligodeoxynucleotides (ODNs) have been applied to regulate gene expression using cell-free media or animal cells. Here we demonstrate the specific inhibition of barley alpha-amylase gene expression by synthetic antisense ODNs. In a cell free system using wheat-germ extracts, 5 microM of a 20-mer antisense ODN prevented the synthesis of the polypeptide corresponding to the predetermined length of alpha-amylase translated in vitro, whereas there was no effect on other protein synthesis. Furthermore, in cultured aleurone cells, alpha-amylase activity was efficiently decreased by addition of ODNs. At the concentrations higher than 5 microM, antisense ODN inhibited alpha-amylase gene expression almost completely. These results imply that ODN could transport into the cultured aleurone cells crossing the cell membrane, and regulate specific gene expression. This simple model system could be applicable not only for the analysis of the alpha-amylase multigene family in barley but also for studying functions of cryptic genes in higher plant.

Cloning and sequence comparisons of four distinct cysteine proteases expressed by Haemonchus contortus adult worms

Three new members of a developmentally regulated cysteine protease gene family of the parasitic nematode Haemonchus contortus have been isolated and characterized. One of the new genes, AC-3, was found to be linked in tandem to the previously characterized AC-2 gene. Nucleotide sequence analyses revealed that the first 90 amino acids of AC-3 are organized into four exons, similar to the situation in AC-2. A cDNA that appears to be a near full-length copy of the AC-3 gene was isolated using the polymerase chain reaction (PCR) technique to amplify cDNAs from adult worm poly(A)+ mRNAs. In addition to AC-3, a distinct cysteine protease cDNA, AC-4, was amplified by the same oligonucleotide primers. cDNAs encoding a fifth cysteine protease, AC-5, were isolated from an adult worm cDNA expression library using specific rabbit antisera and by PCR. Comparison of the predicted amino acid sequences of AC-3, AC-4 and AC-5 reveal that they share 64-77% identity with one another and with the previously reported AC-1 and AC-2 sequences. The amino acids surrounding the active site cysteine are highly conserved, as are the positions of other cysteine residues in the mature protein sequences. The H. contortus proteases are more similar to one another than they are to human cathepsin B (38-44% amino acid identity) or to the Sm31 cysteine protease of Schistosoma mansoni (36-40% identity). Our studies indicate that H. contortus adult worms express mRNAs for several distinct cysteine proteases. The significant primary sequence differences between the proteases suggest that they differ in their substrate specificities and precise physiological functions.

Characterization of a shoot-specific, GA3- and ABA-regulated gene from tomato

A tomato (Lycopersicon esculentum) gene (GAST1) that encodes an RNA whose abundance increases > 20-fold in shoots of the GA-deficient gib1 mutant following spraying with GA3 has been characterized. An increase in GAST1 RNA levels is detectable 2 h after treatment and levels continue to increase for at least an additional 10 h. Between 12 and 24 h following treatment, the amount of GAST1 RNA begins to decline and at 48 h the level is nearly equivalent to that of water-treated control plants. Nuclear runoff analysis indicates that 8 h after treatment with GA3, transcription of the GAST1 gene has increased only threefold, suggesting that GA acts both transcriptionally and post-transcriptionally. ABA partially inhibits the GA-mediated increase in GAST1 RNA abundance while ethephon, kinetin, and 2,4-D have little effect. GAST1 RNA is detectable in untreated leaves, stems, petioles and flowers, but not in roots. The GAST1 gene encodes a 0.7 kb transcript. The sequence of the GAST1 cDNA and genomic clones indicates that the gene is interrupted by three introns and potentially encodes a 112 amino acid protein of unknown function.

RAmy2A; a novel alpha-amylase-encoding gene in rice

The structure and expression of the alpha-amylase-encoding gene, RAmy2A, are described. This only representative of the Amy2 subfamily in rice differs from other cereal alpha-amylase-encoding genes in several respects. It contains the largest introns of all the cereal alpha-amylase-encoding genes examined to date. Moreover, the second of three introns in this gene contains a long inverted repeat sequence that can potentially form a large and stable stem-loop structure in the unspliced RNA transcript. Finally, RAmy2A is constitutively expressed at very low levels in germinated seeds, root, etiolated leaves, immature seeds and callus. This is in marked contrast to the Amy2 genes of wheat and barley which are highly expressed in the aleurone layer of the germinated seeds.

The barley genes Acl1 and Acl3 encoding acyl carrier proteins I and III are located on different chromosomes

Acyl carrier protein (ACP) is an essential cofactor for plant fatty acid synthesis. Three isoforms occur in barley seedling leaves. The genes Acl1 and Acl3 coding for the predominant ACP I and the minor ACP III, respectively, have been cloned and characterized as has a full-length cDNA for ACP III. Both genes, extending over more than 2.5 kb, have a conserved mosaic structure of four exons and three introns which result in mRNAs of ca. 900 bases. Alignment of the DNA sequences demonstrates that homology is restricted to the two exons coding for the mature protein whereas the remaining segments of the genes including the transit peptide-coding domains lack homology. Southern blot analyses demonstrate that Acl1 and Acl3 represent single copy genes located on chromosomes 7 and 1, respectively. Primer extension analyses identified multiple transcription start sites in both genes. The promoter regions are remarkably different; that of Acl3 resembles those for mammalian housekeeping genes in having a high G + C content plus three copies of an RNA polymerase II recognition GC element and in lacking correctly positioned TATA boxes. These features are in accordance with the hypothesis that Acl1 is specifically expressed in leaf tissue whereas Acl3 is a constitutively expressed gene.

Different effects of intron nucleotide composition and secondary structure on pre-mRNA splicing in monocot and dicot plants

We have found previously that the sequences important for recognition of pre-mRNA introns in dicot plants differ from those in the introns of vertebrates and yeast. Neither a conserved branch point nor a polypyrimidine tract, found in yeast and vertebrate introns respectively, are required. Instead, AU-rich sequences, a characteristic feature of dicot plant introns, are essential. Here we show that splicing in protoplasts of maize, a monocot, differs significantly from splicing in a dicot, Nicotiana plumbaginifolia. As in the case of dicots, a conserved branch point and a polypyrimidine tract are not required for intron processing in maize. However, unlike in dicots, AU-rich sequences are not essential, although their presence facilitates splicing if the splice site sequences are not optimal. The lack of an absolute requirement for AU-rich stretches in monocot introns in reflected in the occurrence of GC-rich introns in monocots but not in dicots. We also show that maize protoplasts are able to process a mammalian intron and short introns containing stem--loops, neither of which are spliced in N.plumbaginifolia protoplasts. The ability of maize, but not of N.plumbaginifolia to process stem--loop-containing or GC-rich introns suggests that one of the functions of AU-rich sequences during splicing of dicot plant pre-mRNAs may be to minimize secondary structure within the intron.

cis-acting DNA elements responsive to gibberellin and its antagonist abscisic acid

We have used a transient expression assay in aleurone protoplasts of barley to delineate hormone response elements of the abscisic acid (ABA)-responsive rice gene Rab16A and of the gibberellin A3 (GA3)-responsive barley alpha-amylase gene Amy 1/6-4. Our approach used transcriptional fusions between their 5' upstream sequences and a bacterial chloramphenicol acetyltransferase reporter gene. A chimeric promoter containing six copies of the -181 to -171 region of Rab 16A fused to a minimal promoter conferred ABA-responsive expression on the reporter gene. Transcription from this ABA response element (GTACGTGGCGC) was unaffected by GA3. A chimeric promoter containing six copies of the -148 to -128 sequence of Amy 1/6-4 fused to the minimal promoter conferred GA3-responsive expression on the reporter gene. Transcription from this GA3 response element (GGCCGATAACAAACTCCGGCC) was repressed by ABA. The effect on transcription from both hormone response elements was orientation-independent, indicating that they function as inducible enhancers in their native genes.

Differential expression of alpha-amylase genes in germinating rice and barley seeds

Steady-state levels of mRNA from individual alpha-amylase genes were measured in the embryo and aleurone tissues of rice (Oryza sativa) and two varieties of barley (Hordeum vulgare L. cv. Himalaya and cv. Klages) during germination. Each member of the alpha-amylase multigene families of rice and barley was differentially expressed in each tissue. In rice, alpha-amylase genes displayed tissue-specific expression in which genes RAmy3B, RAmy3C, and RAmy3E were preferentially expressed in the aleurone layer, genes RAmy1A, RAmy1B and RAmy3D were expressed in both the embryo and aleurone, and genes RAmy3A and RAmy2A were not expressed in either tissue. Whenever two or more genes were expressed in any tissue, the rate of mRNA accumulation from each gene was unique. In contrast to rice, barley alpha-amylase gene expression was not tissue-specific. Messenger RNAs encoding low- and high-pI alpha-amylase isozymes were detectable in both the embryo and aleurone and accumulated at different rates in each tissue. In particular, peak levels of mRNA encoding high-pI alpha-amylases always preceded those encoding low-pI alpha-amylases. Two distinct differences in alpha-amylase gene expression were observed between the two barley varieties. Levels of high-pI alpha-amylase mRNA peaked two days earlier in Klages embryos than in Himalaya embryos. Throughout six days of germination, Klages produced three times as much high-pI alpha-amylase mRNA and nearly four times as much low-pI alpha-amylase mRNA than the slower-germinating Himalaya variety.

Control of transient expression of chimaeric genes by gibberellic acid and abscisic acid in protoplasts prepared from mature barley aleurone layers

Gibberellic acid (GA3) and abscisic acid (ABA) control the transcription of alpha-amylase genes in barley aleurone cells. This control is likely to be exerted through cis-acting hormone-responsive elements in the promoter region of the gene. In order to further define these elements, we have developed procedures for obtaining transient expression of chimaeric genes in protoplasts prepared from mature barley aleurone layers. Constructs with heterologous constitutive promoters and with heterologous and homologous GA3- and ABA-regulated promoters were expressed specifically by these cells. This system would appear to offer great potential in gene regulation studies especially for hormonally regulated homologous genes. Functional analysis of a barley alpha-amylase gene has been performed using this system. A 2050 bp fragment from a high-pI alpha-amylase gene was fused to a reporter gene (GUS) and control of its expression was examined. Deletion analysis of this promoter fragment showed that major GA- and ABA-responsive elements occurred between 174 and 41 bp upstream from the transcription initiation site.

The structure of the mouse cathepsin B gene and its putative promoter

The mouse cathepsin B gene and its flanking regions were cloned and characterized. The gene contains 10 exons and 9 introns spanning about 20 kb. Although the exon-intron organization of the mouse cathepsin B gene showed some similarity to the rat cathepsin H and L genes, significant differences were found. In particular, the highly conserved sequence that contains the catalytically active cysteine in these genes is split at different sites by an intron. As with other thiol proteinases, there is no obvious correspondence between the coding exons and structural or functional units within preprocathepsin B. These results suggest that the lysosomal thiol proteinase genes are evolutionarily ancient and that intron shifting has occurred subsequent to their divergence from a common ancestral form. The 5'-flanking region and exon 1 sequences in the mouse cathepsin B gene have a high GC content of approximately 72%. The 5'-flanking region also contains several potential Sp1 binding sites, but lacks TATA and CAAT motifs. These characteristics suggest that cathepsin B is a "housekeeping" gene and its transcription may be controlled by multiple transcription factors, including Sp1.

Barley aleurone layer cell protoplasts as a transient expression system

Protoplasts were prepared from barley aleurone layers using 'Onozuka' cellulase digestion and purification through a Percoll gradient. Protoplasts prepared by this procedure had a viability ranging from 60% to 80% during the first two days of culture. They were responsive to gibberellic acid (GA) as measured by the stimulation of alpha-amylase synthesis. The GA stimulation was counteracted by abscisic acid (ABA). In the presence of polyethylene glycol (PEG), the protoplasts took up exogenously added plasmid DNA containing the reporter gene coding for chloramphenicol acetyl transferase (CAT) linked to a 35S promoter from cauliflower mosaic virus (CaMV) or to barley alpha-amylase gene promoters and expressed CAT activity. Therefore, barley aleurone layer protoplasts are suitable for analysis of hormone-responsive elements in hydrolase genes.

Structural organization and differential expression of rice alpha-amylase genes

Rice alpha-amylases are encoded by a multigene family that has previously been classified into 5 hybridization groups. DNA sequence and Southern blot analysis identified three genes (RAmy1A, RAmy1B and RAmy1C) in Group 1 with DNA sequence identity of at least 90%. Hybridization Group 2 is represented by only one gene, RAmy3D, which is identical to a previously characterized cDNA, pOS137. RAmy3D is physically linked to the sole representative of Group 5, RAmy3E. The identity between these two genes is 81.4% in the coding region but less than 50% in the 5' and 3' flanking regions. Northern blot analysis and RNA-PCR were used to detect the expression of alpha-amylase genes in various tissues. Alpha-amylase mRNA was abundant in germinating seeds and callus. Some genes were also expressed at much lower levels in roots, young leaves and immature seeds. RAmy1A and RAmy3E were expressed in all tissues while RAmy3D was expressed in all tissues except the immature seeds. RAmy1B was weakly expressed only in callus. RAmy1A transcript was most abundant in the germinating seeds, while RAmy3D and RAmy3E transcripts were most abundant in callus and immature seeds, respectively.

Structure and tissue-specific regulation of genes encoding barley (1----3, 1----4)-beta-glucan endohydrolases

Two genes encode (1----3, 1----4)-beta-glucan 4-glucanohydrolase (EC 3.2.1.73) isoenzymes in barley. A gene for isoenzyme EI has been isolated from a barley genomic library and the nucleotide sequence of a 4643 bp fragment determined. The gene is located on barley chromosome 5 while the gene for (1----3, 1----4)-beta-glucanase isoenzyme EII is carried on chromosome 1. The isoenzyme EI gene contains a single 2514 bp intron that is inserted in codon 25 of a sequence encoding a signal peptide of 28 amino acids. The coding region of the mature enzyme is characterized by a high G+C content, which results from an extreme bias towards the use of these nucleotides in the wobble base position of codons. Determination of the nucleotide sequence of the gene has enabled the complete primary structure of the enzyme to be deduced: isoenzyme EI shows 92% positional identity with the primary sequence of (1----3, 1----4)-beta-glucanase isoenzyme EII at both the nucleotide and amino acid level. However, the nucleotide sequences of the two genes diverge markedly in their 3' untranslated regions. Expression sites of the two genes were defined by Northern analysis using oligonucleotide probes specific for these 3' untranslated regions and by amplifying specific cDNAs through the polymerase chain reaction. In the tissues examined, transcription of the isoenzyme EII gene is restricted to the aleurone layer of germinated grain. In contrast, the gene for isoenzyme EI is transcribed at relatively high levels in young leaves, but also in the scutellum and aleurone of germinated grain.

Regulation of α-amylase promoter by gibberellic acid and abscisic acid in barley protoplasts transformed by electroporation

Transient gene expression was studied in isolated protoplasts of barley (Hordeum vulgare L. cv Himalaya) transformed by electroporation. Two plasmid constructions were used, both of which contained the gene coding for neomycin phosphotransferase II (nptII) as a reporter gene. In one plasmid the reporter gene was under the control of an α-amylase group 1 gene promoter of barley and in the other, used as a control, under the CaMV 35S transcript promoter. Protoplasts were isolated from three different types of tissue: the aleurone layer, the scutellar epithelium and the mesophyll. All three types of protoplasts electroporated with 35S -nptII plasmid construction showed strong NPTII activity on which GA3 and ABA had no effect. In protoplasts isolated from the aleurone layer and scutellum the expression of amy-nptII was low when compared with the expression of 35S -nptII. In aleurone protoplasts GA3 enhanced the expression of amy-nptII about tenfold and ABA prevented the action of GA3. In protoplasts isolated from the scutellar epithelium GA3 did not affect the low level of expression of amy-nptII. In mesophyll protoplasts the amy-nptII was not expressed at all.

In Vitro Processing of Aleurain, a Barley Vacuolar Thiol Protease

Aleurain, originally described from its cDNA as a thiol protease [Rogers, J.C., Dean, D., and Heck, G.R. (1985). Proc. Natl. Acad. Sci. USA 82, 6512-6516], is characterized here as a glycoprotein that is targeted to a distinct vacuolar compartment in aleurone cells. Monospecific antibodies to a bacterial trpE-aleurain fusion protein were used to show that aleurain is made as a 42-kilodalton (kD) proenzyme (proaleurain) that is proteolytically processed in a post-Golgi compartment in two steps to form a 32-kD protein. The first processing step is the discrete loss of 9 kD from proaleurain to yield a 33-kD intermediate that is further processed by the gradual loss of 1 kD resulting in mature 32-kD aleurain. Using proaleurain secreted from Xenopus oocytes as a substrate, we established an in vitro system using aleurone cell extracts that correctly processes proaleurain to a stable protein that is indistinguishable from native barley aleurain as judged by partial digestion with staphylococcal V8 protease. Proaleurain is not capable of self-cleavage in the absence of aleurone cell extracts and mature aleurain appears not to participate in processing in vitro.

Gene structure of mouse cathepsin B

The structure of a genomic DNA fragment encoding mouse cathepsin B was characterized. The genomic insert spans 15 kbp and contains 9 exons encoding the 339 amino acid residues of mouse preprocathepsin B. Intron break-points are not found at the junctions of the pre-peptide, pro-peptide and mature enzyme. Like other cysteine proteinase genes, the region around the cysteinyl active site is split by an intron, but in contrast with cathepsins L and H the intron break-point is located immediately after the active site.

Classification and characterization of the rice alpha-amylase multigene family

To establish the size and organization of the rice alpha-amylase multigene family, we have isolated 30 alpha-amylase clones from three independent genomic libraries. Partial characterization of these clones indicates that they fall into 5 hybridization groups containing a total of 10 genes. Two clones belonging to the Group 3 hybridization class have more than one gene per cloned fragment. The nucleotide sequence of one clone from Group 1, lambda OSg2, was determined and compared to other known cereal alpha-amylase sequences revealing that lambda OSg2 is the genomic analog of the rice cDNA clone, pOS103. The rice alpha-amylase genes in Group 1 are analogous to the alpha-Amy1 genes in barley and wheat. lambda OSg2 contains sequence motifs common to most actively transcribed genes in plants. Two consensus sequences, TAACAAGA and TATCCAT, were found in the 5' flanking regions of alpha-amylase genes of rice, barley and wheat. The former sequence may be specific to alpha-amylase gene while the latter sequence may be related to a 'CATC' box found in many plant genes. Another sequence called the pyrimidine box (TCCTTTTTC) was found in the alpha-amylase genes as well as other genes regulated by gibberellic acid (GA). Comparisons based on amino acid sequence alignment revealed that the multigene families in rice, barley and wheat shared a common ancestor which contained three introns. Some of the descendants of the progenitor alpha-amylase gene appear to have lost the middle intron while others maintain all three introns.

The alpha-amylase genes in Oryza sativa: characterization of cDNA clones and mRNA expression during seed germination

Two cDNA clones, pOS103 and pOS137, were isolated which code for distinct alpha-amylase isozymes in germinating rice seeds. Sequence analysis indicated that the clones encode polypeptides of approximately 48 kDa, both of which possess a signal peptide involved in directing secretion of the protein. Comparison of the two rice alpha-amylase amino acid sequence showed that they are 76% similar to each other, while showing 85% to 90% similarity with other cereal alpha-amylases. A comparison of eleven cereal alpha-amylases also revealed three new conserved regions (I', II', and IV') not previously identified in the animal, bacterial, and fungal alpha-amylases. Regions I' and IV' are sites for intron splicing while region II' is probably involved in calcium binding. One of the rice alpha-amylase cDNAs, pOS103, encodes a protein that has two potential N-glycosylation sites, one in the signal peptide and the other in the mature portion of the protein. The cDNA clone, pOS137, encodes an alpha-amylase with a single glycosylation site in the signal peptide, suggesting that the mature OS137 isozyme is not glycosylated. Analysis of the expression of these genes in germinating rice seeds indicated that mRNA corresponding to pOS103 and pOS137 could be detected throughout a 48 h period of seed imbibition. RNA levels, however, were dramatically stimulated by treatment of embryoless half-seeds with exogenous GA3. Our results demonstrate that at least two forms of alpha-amylase are expressed in germinating rice seeds and that the expression of these genes is regulated by the phytohormone GA3.

Gene structure of rat cathepsin H

The gene structure of rat cathepsin H was determined. It comprises at least 12 exons of various lengths (32-433 bp) spanning in total more than 17.5 kbp. The gene structure does not correspond well to the functional unit of the proteinase. The region around the active site Cys residue, the most conserved region among cysteine proteinases, is split by an intron. This is a common characteristic among the gene structures of cysteine proteinases.

Barley alpha-amylase genes and the thiol protease gene Aleurain: use of a single poly(A) addition signal associated with a conserved pentanucleotide at the cleavage site

Plant genes usually have multiple potential poly(A) addition signals, and different sites are used for 3' processing of transcripts from a single gene. In contrast, we show here that four barley genes that also have multiple poly(A) addition signals conforming to the plant consensus use only one signal. In each of these genes, the region of cleavage for poly(A) addition is centered on a conserved pentanucleotide. This AGGCA is followed by a conserved sequence homologous to sequences involved in self-cleavage of plant viroid RNA precursors; immediately following, in turn, are four or five nucleotides complementary to the nucleotides immediately preceding AGGCA in each gene. The presence of these conserved sequences and their association with a single region for poly(A) addition in three different gene types (high-pI and low-pI alpha-amylase genes and a thiol protease) that otherwise are not homologous in their 3' untranslated/flanking sequences suggest that they might participate in some common regulatory mechanism shared by these genes.