Acetolactate synthase from Brassica napus: Immunological characterization and quaternary structure of the native enzyme

Acetolactate synthase (ALS, AHAS; EC 4. 1. 3. 18) from Brassica napus has been partially purified and characterized using polyclonal antibodies. Following denaturing sodium dodecyl sulphate polyacrylamide gel electrophoresis and western blot analysis, 65 and 66 kDa ALS subunit polypeptides were immunologically detected, along with a novel 36 kDa polypeptide which cross-reacted with the anti-ALS antibody. Partial peptide sequencing of the 36 kDa peptide revealed significant similarity to plant aldolase proteins. ALS activity from stromal extracts fractionated by gel filtration chromatography as a single species of estimated molecular mass of 124 kDa, while comparative sedimentation coefficient in glycerol gradients indicated a corresponding molecular mass of 132 kDa. The results suggest that the native enzyme is a dimer of 65 and/or 66 kDa subunits. Anion exchange chromatography resolved two classes of ALS activity of equal native molecular weight, but which exhibited different properties with respect to subunit structure, sensitivity to inhibition by chlorsulfuron and feedback inhibition by branched chain amino acids.     

The N-terminal domain of the regulatory subunit is sufficient for complete activation of acetohydroxyacid synthase III from Escherichia coli

We have previously proposed a model for the fold of the N-terminal domain of the small, regulatory subunit (SSU) of acetohydroxyacid synthase isozyme III. The fold is an alpha-beta sandwich with betaalphabetabetaalphabeta topology, structurally homologous to the C-terminal regulatory domain of 3-phosphoglycerate dehydrogenase. We suggested that the N-terminal domains of a pair of SSUs interact in the holoenzyme to form two binding sites for the feedback inhibitor valine in the interface between them. The model was supported by mutational analysis and other evidence. We have now examined the role of the C-terminal portion of the SSU by construction of truncated polypeptides (lacking 35, 48, 80, 95, or 112 amino acid residues from the C terminus) and examining the properties of holoenzymes reconstituted using these constructs. The Delta35, Delta48, and Delta80 constructs all lead to essentially complete activation of the catalytic subunits. The Delta80 construct, corresponding to the putative N-terminal domain, has the highest level of affinity for the catalytic subunits and leads to a reconstituted enzyme with k(cat)/K(M) about twice that of the wild-type enzyme. On the other hand, none of these constructs binds valine or leads to a valine-sensitive enzyme on reconstitution. The enzyme reconstituted with the Delta80 construct does not bind valine, either. The N-terminal portion (about 80 amino acid residues) of the SSU is thus necessary and sufficient for recognition and activation of the catalytic subunits, but the C-terminal half of the SSU is required for valine binding and response. We suggest that the C-terminal region of the SSU contributes to monomer-monomer interactions, and provide additional experimental evidence for this suggestion.     

Acetohydroxyacid synthase: a proposed structure for regulatory subunits supported by evidence from mutagenesis

Valine inhibition of acetohydroxyacid synthase (AHAS) plays an important role in regulation of biosynthesis of branched-chain amino acids in bacteria. Bacterial AHASs are composed of separate catalytic and regulatory subunits; while the catalytic subunits appear to be homologous with several other thiamin diphosphate-dependent enzymes, there has been no model for the structure of the small, regulatory subunits (SSUs). AHAS III is one of three isozymes in Escherichia coli. Its large subunit (encoded by ilvI) by itself has 3-5 % activity of the holoenzyme and is not sensitive to inhibition by valine. The SSU (encoded by ilvH) associates with the large subunit and is required for full catalytic activity and valine sensitivity. The isolated SSU binds valine. The properties of several mutant SSUs shed light on the relation between their structure and regulatory function. Three mutant SSUs were obtained from spontaneous Val(R) bacterial mutants and three more were designed on the basis of an alignment of SSU sequences from valine-sensitive and resistant isozymes, or consideration of the molecular model developed here. Mutant SSUs N11A, G14D, N29H and A36V, when reconstituted with wild-type large subunit, lead to a holoenzyme with drastically reduced valine sensitivity, but with a specific activity similar to that of the wild-type. The isolated G14D and N29H subunits do not bind valine. Mutant Q59L leads to a valine-sensitive holoenzyme and isolated Q59L binds valine. T34I has an intermediate valine sensitivity. The effects of mutations on the affinity of the large subunits for SSUs also vary. D. Fischer's hybrid fold prediction method suggested a fold similarity between the N terminus of the ilvH product and the C-terminal regulatory domain of 3-phosphoglycerate dehydrogenase. On the basis of this prediction, together with the properties of the mutants, a model for the structure of the AHAS SSUs and the location of the valine-binding sites can be proposed.     

Molecular characterization of cDNAs encoding G protein alpha and beta subunits and study of their temporal and spatial expression patterns in Nicotiana plumbaginifolia Viv

We have isolated cDNA sequences encoding alpha and beta subunits of potential G proteins from a cDNA library prepared from somatic embryos of Nicotiana plumbaginifolia Viv. at early developmental stages. The predicted NPGPA1 and NPGPB1 gene products are 75-98% identical to the known respective plant alpha and beta subunits. Southern hybridizations indicate that NPGPA1 is probably a single-copy gene, whereas at least two copies of NPGPB1 exist in the N. plumbaginifolia genome. Northern analyses reveal that both NPGPA1 and NPGPB1 mRNA are expressed in all embryogenic stages and plant tissues examined and their expression is obviously regulated by the plant hormone auxin. Immunohistological localization of NPGPalpha1 and NPGPbeta1 preferentially on plasma and endoplasmic reticulum membranes and their immunochemical detection exclusively in microsomal cell fractions implicate membrane association of both proteins. The temporal and spatial expression patterns of NPGPA1 and NPGPB1 show conformity as well as differences. This could account for not only cooperative, but also individual activities of both subunits during embryogenesis and plant development.     

Divergent genes for translation initiation factor eIF-4A are coordinately expressed in tobacco.

Three cDNA clones coding for eukaryotic translation initiation factor 4A, eIF-4A, were isolated from a Nicotiana plumbaginifolia root cDNA library by heterologous screening. The clones comprise two distinct gene classes as two clones are highly similar while the third is divergent. The genes belong to a highly conserved gene family, the DEAD box supergene family, although the divergent clone contains a DESD box rather than the characteristic DEAD box. The two clones are representatives of separate small multigene families in both N. plumbaginifolia and N. tabacum. Representatives of each family are coordinately expressed in all plant organs examined. The 47 kD polypeptide product of one clone, overexpressed in E. coli, crossreacts immunologically with a rabbit reticulocyte eIF-4A polyclonal antibody. Taken together the data suggest that the two Nicotiana eIF-4A genes encode translation initiation factors. The sequence divergence and the coordinate expression of the two Nicotiana eIF-4A families provide an excellent system to determine if functionally distinct eIF-4A polypeptides are required for translation initiation in plants.     

Mechanistic insight into the ribosome biogenesis functions of the ancient protein KsgA

While the general blueprint of ribosome biogenesis is evolutionarily conserved, most details have diverged considerably. A striking exception to this divergence is the universally conserved KsgA/Dim1p enzyme family, which modifies two adjacent adenosines in the terminal helix of small subunit ribosomal RNA (rRNA). While localization of KsgA on 30S subunits [small ribosomal subunits (SSUs)] and genetic interaction data have suggested that KsgA acts as a ribosome biogenesis factor, mechanistic details and a rationale for its extreme conservation are still lacking. To begin to address these questions we have characterized the function of Escherichia coli KsgA in vivo using both a ksgA deletion strain and a methyltransferase-deficient form of this protein. Our data reveal cold sensitivity and altered ribosomal profiles are associated with a DeltaksgA genotype in E. coli. Our work also indicates that loss of KsgA alters 16S rRNA processing. These findings allow KsgAs role in SSU biogenesis to be integrated into the network of other identified factors. Moreover, a methyltransferase-inactive form of KsgA, which we show to be deleterious to cell growth, profoundly impairs ribosome biogenesis-prompting discussion of KsgA as a possible antimicrobial drug target. These unexpected data suggest that methylation is a second layer of function for KsgA and that its critical role is as a supervisor of biogenesis of SSUs in vivo. These new findings and this proposed regulatory role offer a mechanistic explanation for the extreme conservation of the KsgA/Dim1p enzyme family.     

Expression of the human alpha-galactosidase A in Escherichia coli K-12

We used the prokaryotic expression vector, ptrpL1, for the expression in Escherichia coli K-12 of a cDNA clone specific for the human lysosomal hydrolase, alpha-galactosidase A. The 5' terminus of the cDNA clone was engineered so that an ATG codon precedes the first codon of the mature form of the enzyme. A clone with elevated expression of this human enzyme was constructed by increasing the distance between the Shine-Dalgarno site and the ATG start codon from 6 to 8 bp. Clones with alpha-galactosidase A specific cDNA encoding the proenzyme produce a protein of 45 kDa, the size expected for the intact proenzyme. The 45-kDa protein is specifically precipitated by antibody to alpha-galactosidase A, and its expression is repressed by tryptophan and induced by 3-beta-indoleacrylic acid as expected for this expression vector. The human enzyme is produced in E. coli in a catalytically active form at levels sufficient to support the growth of cells using alpha-galactosides as sole sources of carbon and energy. In addition, bacterial colonies that produce the human enzyme turn blue in the presence of 5-bromo-4-chloro-3-indolyl-alpha-D-galactopyranoside.     

Maize glutathione-dependent formaldehyde dehydrogenase cDNA: a novel plant gene of detoxification

We have previously shown that intact plants and cultured plant cells can metabolize and detoxify formaldehyde through the action of a glutathione-dependent formaldehyde dehydrogenase (FDH), followed by C-1 metabolism of the initial metabolite (formic acid). The cloning and heterologous expression of a cDNA for the glutathione-dependent formaldehyde dehydrogenase from Zea mays L. is now described. The functional expression of the maize cDNA in Escherichia coli proved that the cloned enzyme catalyses the NAD⁺- and glutathione (GSH)-dependent oxidation of formaldehyde. The deduced amino acid sequence of 41 kDa was on average 65% identical with class III alcohol dehydrogenases from animals and less than 60% identical with conventional plant alcohol dehydrogenases (ADH) utilizing ethanol. Genomic analysis suggested the existence of a single gene for this cDNA. Phylogenetic analysis supports the convergent evolution of ethanol-consuming ADHs in animals and plants from formaldehyde-detoxifying ancestors. The high structural conservation of present-day glutathione-dependent FDH in microorganisms, plants and animals is consistent with a universal importance of these detoxifying enzymes.     

Variability in Ribulose-1,5-Bisphosphate Carboxylase/Oxygenase Small Subunits and Carboxylation Activity in Fern Gametophytes Grown under Different Light Spectra

Two distinct ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco) small subunit (SSU) populations were observed in Pteris vittata gametophytes grown under different illumination conditions. Exposure of the fern gametophytes to continuous red light (R) resulted in Rubisco SSUs that were not recognized by polyclonal antibodies raised against SSUs from spinach. Unlike the R-induced SSUs, blue light (B) induced SSUs were well recognized. This difference in SSU composition also reflected in Rubisco activity. In vitro, B-induced Rubisco exhibits a significantly higher carboxylation activity as compared to the R-induced Rubisco. Approximately a two- to threefold increase in the V_max value of the B-induced carboxylase as compared to the R-induced one was measured. It thus seems very likely that certain domains in the SSU molecule affect enzyme activity.     

Cloning and sequence analysis of a cDNA for human glycosylasparaginase. A single gene encodes the subunits of this lysosomal amidase

We have isolated a full-length cDNA (HPAsn.6) for human placenta glycosylasparaginase using a 221-bp PCR amplified fragment containing rat liver asparaginase gene sequences. The deduced amino acid sequence from the human clone showed sequence identity to both the alpha and beta subunits of the rat enzyme. The human enzyme is encoded as a 34.6 kDa polypeptide that is post-translationally processed to generate two subunits of approx. 19.5 (alpha) and 15 (beta) kDa. A charge enriched region is present at the predicted site where cleavage occurs. Using polyclonal antibodies against the alpha and beta subunits of rat liver asparaginase, we have shown that the human enzyme is similar in structure to the rat enzyme.     

Isolation,characterization and molecular cloning of the mannose-binding lectins from leaves and roots of garlic (Allium sativum L.)

Two novel lectins were isolated from roots and leaves of garlic. Characterization of the purified proteins indicated that the leaf lectin ASAL is a dimer of two identical subunits of 12 kDa, which closely resembles the leaf lectins from onion, leek and shallot with respect to its molecular structure and agglutination activity. In contrast, the root lectin ASARI, which is a dimer of subunits of 15 kDa, strongly differs from the leaf lectin with respect to its agglutination activity. cDNA cloning of the leaf and root lectins revealed that the deduced amino acid sequences of ASAL and ASARI are virtually identical. Since both lectins have identical N-terminal sequences the larger Mr of the ASARI subunits implies that the root lectin has an extra sequence at its C-terminus. These results not only demonstrate that virtually identical precursor polypeptides are differently processed at their C-terminus in roots and leaves but also indicate that differential processing yields mature lectins with strongly different biological activities. Further screening of the cDNA library for garlic roots also yielded a cDNA clone encoding a protein composed of two tandemly arrayed lectin domains. Since the presumed two-domain root lectin has not been isolated yet, its possible relationship to the previously described two-domain bulb lectin could not be studied at the protein level.     

Cloning and expression profile of human inorganic pyrophosphatase.

We have cloned a 1.23 kb cDNA from a human heart library which encodes a 32 kDa protein that is 94% identical to bovine inorganic pyrophosphatase. The protein contains an aspartate-rich signature sequence that was previously identified in yeast and prokaryotic pyrophosphatases. Our clone detects a single band on Northern blots and is expressed at modest levels in all tissues examined. The cDNA shows linkage to markers on the long arm of chromosome 10.     

Characterization of methylmalonyl-CoA mutase involved in the propionate photoassimilation of Euglena gracilis Z

Significant accumulation of the methylmalonyl-CoA mutase apoenzyme was observed in the photosynthetic flagellate Euglena gracilis Z at the end of the logarithmic growth phase. The apoenzyme was converted to a holoenzyme by incubation for 4 h at 4°C with 10 μM 5′-deoxyadenosylcobalamin, and then, the holoenzyme was purified to homogeneity and characterized. The apparent molecular mass of the enzyme was calculated to be 149.0 kDa ± 5.0 kDa using Superdex 200 gel filtration. SDS–polyacrylamide gel electrophoresis of the purified enzyme yielded a single protein band with an apparent molecular mass of 75.0 kDa ± 3.0 kDa, indicating that the Euglena enzyme is composed of two identical subunits. The purified enzyme contained one mole of prosthetic 5′-deoxyadenosylcobalamin per mole of the enzyme subunit. Moreover, we cloned the full-length cDNA of the Euglena enzyme. The cDNA clone contained an open reading frame encoding a protein of 717 amino acids with a calculated molecular mass of 78.3 kDa, preceded by a putative mitochondrial targeting signal consisting of nine amino acid residues. Furthermore, we studied some properties and physiological function of the Euglena enzyme.     

Existence of two gamma subunits of the G proteins in brain

Although amino acid sequences have been determined for the alpha and beta subunits of Gs, Gi, and Go, sequences have not been reported for the gamma subunits of these G proteins. In the present paper, we determined the sequences of peptides prepared by partial proteolysis of two different forms of the gamma subunit of Gs, Gi, and Go from bovine brain. Using oligonucleotide probes based on the sequences of two of these peptides, a cDNA clone was isolated from a bovine adrenal cDNA library. This clone contained a 0.9-kilobase cDNA insert that included an open reading frame of 213 bases encoding a 71-amino acid polypeptide with an estimated Mr of 7850. The amino acid sequence predicted for the adrenal cDNA clone was identical to that determined for one form of the gamma subunit from brain. In addition, an antibody to a peptide based on the predicted amino acid sequence of this cDNA clone reacted specifically with one of the brain gamma subunits, indicating the adrenal cDNA clone encodes a gamma subunit present in both adrenal gland and brain. Also, evidence is presented, demonstrating the existence of a second, structurally distinct, form of the gamma subunit of Gs, Gi, and Go in brain.     

A Local Role for the Small Ribosomal Subunit Primary Binder rpS5 in Final 18S rRNA Processing in Yeast

In vivo depletion of the yeast small ribosomal subunit (SSU) protein S5 (rpS5) leads to nuclear degradation of nascent SSUs and to a perturbed global assembly state of the SSU head domain. Here, we report that rpS5 plays an additional local role at the head/platform interface in efficient SSU maturation. We find that yeast small ribosomal subunits which incorporated an rpS5 variant lacking the seven C-terminal amino acids have a largely assembled head domain and are exported to the cytoplasm. On the other hand, 3′ processing of 18S rRNA precursors is inhibited in these ribosomal particles, although they associate with the putative endonuclease Nob1p and other late acting 40S biogenesis factors. We suggest that the SSU head component rpS5 and platform components as rpS14 are crucial constituents of a highly defined spatial arrangement in the head – platform interface of nascent SSUs, which is required for efficient processing of the therein predicted SSU rRNA 3′ end. Positioning of rpS5 in nascent SSUs, including its relative orientation towards platform components in the head-platform cleft, will depend on the general assembly and folding state of the head domain. Therefore, the suggested model can explain 18S precursor rRNA 3′ processing phenotypes observed in many eukaryotic SSU head assembly mutants.     

Cloning and characterization of human guanine deaminase. Purification and partial amino acid sequence of the mouse protein

Mouse erythrocyte guanine deaminase has been purified to homogeneity. The native enzyme was dimeric, being comprised of two identical subunits of approximately 50,000 Da. The protein sequence was obtained from five cyanogen bromide cleavage products giving sequences ranging from 12 to 25 amino acids in length and corresponding to 99 residues. Basic Local Alignment Search Tool (BLAST) analysis of expressed sequence databases enabled the retrieval of a human expressed sequence tag cDNA clone highly homologous to one of the mouse peptide sequences. The presumed coding region of this clone was used to screen a human kidney cDNA library and secondarily to polymerase chain reaction-amplify the full-length coding sequence of the human brain cDNA corresponding to an open reading frame of 1365 nucleotides and encoding a protein of 51,040 Da. Comparison of the mouse peptide sequences with the inferred human protein sequence revealed 88 of 99 residues to be identical. The human coding sequence of the putative enzyme was subcloned into the bacterial expression vector pMAL-c2, expressed, purified, and characterized as having guanine deaminase activity with a Km for guanine of 9.5 +/- 1.7 microM. The protein shares a 9-residue motif with other aminohydrolases and amidohydrolases (PGX[VI]DXH[TVI]H) that has been shown to be ligated with heavy metal ions, commonly zinc. The purified recombinant guanine deaminase was found to contain approximately 1 atom of zinc per 51-kDa monomer.     

The closely related homomeric and heterodimeric mannose-binding lectins from garlic are encoded by one-domain and two-domain lectin genes, respectively.

Lectin cDNA clones for two different lectins from garlic (Allium sativum L.) bulbs, ASAI and ASAII (ASA, Allium sativum agglutinin), were isolated and characterized. The first lectin, ASAI, is a heterodimer composed of two different subunits of 11.5 kDa and 12.5 kDa. It is translated from an mRNA of 1400 nucleotides encoding a polypeptide of 306 amino acids with two very similar domains. N-terminal sequencing of the two polypeptides of the mature lectin confirmed that both subunits are derived from the same precursor and that each corresponds to one of the two domains in the sequence. In contrast to ASAI, the second garlic lectin, ASAII, is a homodimer of two identical 12-kDa subunits. It is translated from an mRNA of approximately 800 nucleotides encoding a polypeptide of 154 amino acids. Interestingly, the coding region of the ASAII cDNA clones is almost identical to that of the second domain of the ASAI cDNA clones.