Biochemical properties of duplicated isozymes of phosphoglucose isomerase in the plant Clarkia xantiana

The structural gene locus specifying subunits of the cytoplasmic isozymes of phosphoglucose isomerase (PGI) is present in duplicate in many diploid species of Clarkia (Onagraceae), a genus of annual plants native to California. We studied the kinetic properties and molecular weights of a large number of genetically defined and highly purified PGIs in C. xantiana, a species with the duplication, as a means of examining the biochemical consequences of the evolution of a new gene locus. This species is primarily outcrossing, but also includes several previously described predominantly self-pollinating populations. Both cytoplasmic PGI loci in the outcrossing populations are polymorphic and their enzyme products are readily separated by electrophoresis. The PGIs from the outcrossing populations were generally closely similar in molecular weight, pH optimum, heat sensitivity, energy of activation, and apparent K _m (fructose-6-phosphate). The PGI loci in the selfing populations are monomorphic and specify enzymes having identical electrophoretic mobilities to those coded by the most frequent alleles of the outcrosser. The PGI isozymes in the selfers differed fivefold in K _m , suggesting that they have a very different catalytic effectiveness. The high K _m of the PGI-3A isozyme (1.1mm) was anomalous among the examined and would likely be disadvantageous in a species which lacked other more normally functioning PGIs. But in the cytoplasm of the selfing plants, it is present with other PGIs that have low K _m values. The PGI-3A enzyme is a good candidate for a gene product coded by a forbidden mutation that could not have been established in the absence of the duplication. The rationale for this suggestion is described and it is also pointed out that the divergence of duplicated genes is influenced by many factors such as the breeding system and other population factors as well as the effect of particular mutations.This research was supported by NSF Grant DEB77-08448.     

Plant phosphoglucose isomerase genes lack introns and are expressed in Escherichia coli

Nuclear genes that appear to encode both cytosolic and plastid isozymes of phosphoglucose isomerase (PGI), an essential glycolytic enzyme, have been isolated from three diploid species of the annual wild flower genus Clarkia (Onagraceae). The genes do not contain introns and are expressed to varying degrees in Escherichia coli when cloned in either Charon 35 phage or pUC plasmid vectors. The PGI proteins synthesized in E. coli form dimers, are catalytically active, and their electrophoretic mobilities are similar to those of appropriate Clarkia PGIs. The nucleotide sequence of a gene encoding a plastid isozyme of C. unguiculata is described.     

Molecular assays of pollen use consistently reflect pollinator visitation patterns in a system of flowering plants

Determining how pollinators visit plants vs. how they carry and transfer pollen is an ongoing project in pollination ecology. The current tools for identifying the pollens that bees carry have different strengths and weaknesses when used for ecological inference. In this study we use three methods to better understand a system of congeneric, coflowering plants in the genus Clarkia and their bee pollinators: observations of plant–pollinator contact in the field, and two different molecular methods to estimate the relative abundance of each Clarkia pollen in samples collected from pollinators. We use these methods to investigate if observations of plant–pollinator contact in the field correspond to the pollen bees carry; if individual bees carry Clarkia pollens in predictable ways, based on previous knowledge of their foraging behaviors; and how the three approaches differ for understanding plant–pollinator interactions. We find that observations of plant–pollinator contact are generally predictive of the pollens that bees carry while foraging, and network topologies using the three different methods are statistically indistinguishable from each other. Results from molecular pollen analysis also show that while bees can carry multiple species of Clarkia at the same time, they often carry one species of pollen. Our work contributes to the growing body of literature aimed at resolving how pollinators use floral resources. We suggest our novel relative amplicon quantification method as another tool in the developing molecular ecology and pollination biology toolbox.     

Low molecular weight subunits associated with the cytochrome b 6 f complexes from spinach and Chlamydomonas reinhardtii

Cytochrome b ₆ f complexes, prepared from spinach and Chlamydomonas thylakoids, have been examined for their content of low molecular weight subunits. The spinach complex contains two prominent low molecular weight subunits of 3.7 and 4.1 kD while a single prominent component of 4.5 kD was present in the Chlamydomonas complex. An estimation of the relative stoichiometry of these subunits suggests several are present at levels approximating one copy per cytochrome complex. The low molecular weight subunits were purified by reversed phase HPLC and N-terminal sequences obtained. Both the spinach and Chlamydomonas cytochrome complexes contain a subunit that is identified as the previously characterized petG gene product (4.8 kD in spinach and 4.1 kD in Chlamydomonas). A second subunit (3.8 kD in spinach and 3.7 kD in Chlamydomonas) appears to be homologous in the two complexes and is likely to be a nuclear gene product. The possible presence of other low molecular weight subunits in these complexes is also considered.     

Novel Chaperonins in a Prokaryote

Group II chaperonins belong to the Hsp60 family occurring in archaea and eukaryotes. The archaeal chaperonins build the thermosome, which is similar to the eukaryotic CCT (chaperonin-containing TCP-1). Eukaryotes have eight subunits, and up until now, it was thought that archaea had between one and three subunits, depending on the species. We now report two novel subunits, termed Hsp60-4 and Hsp60-5, in the archaeon Methanosarcina acetivorans, which also has Hsp60-1, Hsp60-2, and Hsp60-3 with orthologs in Methanosarcinae. Hsp60-4 and Hsp60-5 occur only in M. acetivorans, which makes this organism unique in that it has the highest number of chaperonin subunits ever described for an archaeon. Evolutionary analysis suggests that either Hsp60-4 or Hsp60-5 paralogs have arisen by gene duplication with vastly increased accepted substitution rates or that they represent ancestral types found only in this species.Reviewing Editor: Dr. W. Ford Doolittle     

Evidence for duplication and divergence of the structural gene for phosphoglucoisomerase in diploid species of clarkia

Formal genetic analysis of the mode of inheritance of the electrophoretic phenotypes for phosphoglucoisomerase (PGI) in the annual plants Clarkia rubicunda and C. xantiana showed that these diploid species have two and three genes, respectively, that specify PGI subunits. Electrophoretic examination of seven other diploid species of Clarkia revealed that species assigned to ancestral sections in the current taxonomy have two PGI genes, whereas more specialized species have three PGI genes. Together with evidence that diploid species in two closely related genera have two PGI genes, this suggests the third PGI gene arose within Clarkia. Intergenic heterodimers are formed between polypeptides specified by the third gene and one of the other PGI genes, indicating they have a high degree of structural similarity. The combined genetic, biochemical, and phylogenetic evidence suggests that the third PGI gene resulted from a process of gene duplication. The apparent Michaelis constants (F6P to G6P) of the most common electrophoretic variants of the ancestral gene in C. xantiana and in C. rubicunda are closely similar, but that of the duplicate enzyme is much higher. The intergenic heteromer has an intermediate value. Four alleles have been identified for the duplicate PGI gene in C. xantiana, including a null allele which eliminates the activity of its product. This allele is one of the few examples of a "silenced" duplicate gene. The ancestral and duplicate genes assort independently in C. xantiana. In conjunction with the substantial chromosomal rearrangements that characterize species of Clarkia, this may mean that the duplicate PGI marks a duplicated chromosomal segment that originated from a cross between partially overlapping reciprocal translocations rather than from unequal crossing over.     

PHYLOGENETIC IMPLICATIONS OF DIFFERENCES IN NUMBER OF PLASTID PHOSPHOGLUCOSE ISOMERASE ISOZYMES IN NORTH AMERICAN COREOPSIS (ASTERACEAE: HELIANTHEAE: COREOPSIDINAE)

Enzyme electrophoresis was employed to ascertain the number of loci encoding plastid phosphoglucose isomerase (PGI) in species representing all sections of North American Coreopsis. Several species from each of the closely related genera Bidens, Coreocarpus, Cosmos, and Thelesperma were also examined. Species in nine of the 11 sections of North American Coreopsis have two isozymes for plastid PGI, and nearly all species examined in the four other genera also have two (one species has three) isozymes. Since most diploid vascular plants have one plastid PGI isozyme, a gene duplication probably occurred in an ancestor that is common to Coreopsis and the other four genera. That is, two isozymes represent the ancestral number for Coreopsis. The two sections (Electra and Anathysana) apparently lacking the duplication are closely related woody plants restricted largely to Mexico. One gene encoding plastid PGI ostensibly was silenced in a common ancestor of these two sections. This is concordant with other data suggesting a close relationship between the two sections, i.e., they appear to represent a monophyletic group. The electrophoretic data also indicate that 1) the enigmatic monotypic section Silphidium is more closely related to eastern North American sections and not derived from section Electra; and 2) section Anathysana is not ancestral to the three California sections Leptosyne, Pugiopappus, and Tuckermannia; rather, it represents a terminal element closely related to and possibly derived from section Electra.     

Subunit hybridization and immunological studies of duplicated phosphoglucose isomerase isozymes

We examined structural and functional properties of the recently duplicated cytosolic isozymes of phosphoglucose isomerase (PGI) (EC 5.3.1.9) of the wild plant Clarkia xantiana and related species. A new purification protocol yielded PGIs with high specific activities. The duplicated PGI isozymes showed similar substrate affinities (apparent Km) in both catalytic directions. A newly devised competitive enzyme-linked immunosorbent assay (ELISA), using polyclonal antibodies, distinguished sodium dodecyl sulfate (SDS)-denatured PGIs coded by the duplicated loci but did not discriminate between allelic products of one of the loci. In vitro dissociation and reassociation experiments revealed that the duplicated subunits differed in their efficiency of reassociation. The difference was closely correlated with differences between the isozymes in their in vivo accumulation. In contrast, allelic subunits in species with or without the duplication were able to reassociate with similar efficiency. The duplicated PGI isozymes have diverged more in structural properties than kinetic ones. The total evidence suggests that mechanisms have evolved which reduce the potential consequences of the duplication.     

Phosphoglucose isomerase from Escherischia coli K10: Purification,properties and formation under aerobic and anaerobic condition

Phosphoglucose isomerase has been purified from crude extracts of Escherichia coli K10. Two forms of the enzyme were separated during the purification procedure. The major species comprises more than 90% of the enzyme activity, has an apparent molecular weight of about 125,000 and consists of two 59,000 molecular weight subunits; the minor species has an apparent size of 230,000 and consists of (possibly four) subunits of 59,000 molecular weight. Both enzyme forms have the same N-terminal amino acid, the same pH optimum of reaction and the same kinetic constants for the substrate fructose-6-phosphate and the inhibitor 6-phosphogluconate. They differ in that the minor species has half the specific enzyme activity compared to the major one and that its subunit polypeptide carries a higher electronegative charge. Since they are both coded by the pgi gene and since they show full immunological identity it seems that the minor species is a dimer of the major enzyme form and that dimerisation is caused by subunit modification. No physiological role could be found for the existence of the two forms. — Formation of phosphoglucose isomerase is under respiratory control: under anaerobiosis the enzyme (both species) is derepressed parallely with other glycolytic enzymes.Dedicated to Professor Dr. O. Kandler on the occasion of his 60th birthday     

Genetics,subcellular localization,and molecular characterization of 6-phosphogluconate dehydrogenase isozymes in tomato

Three independent genes are responsible for 6-phosphogluconate dehydrogenase (6PGDH) activity in tomato. 6Pgdh-2, located on chromosome 12, codes for subunits of an active dimer which is restricted to the plastids. 6Pgdh-1, chromosome 4, and 6Pgdh-3, chromosome 5, code for subunits which form three dimers—two homodimers and an intergenic heterodimer. The latter three isozymes are found in the cytosol. 6Pgdh-1, 6Pgdh-2, and 6Pgdh-3 code for subunits with estimated molecular weights of 49,500, 50,500, and 51,200, respectively. The intergenic heterodimer encoded by 6Pgdh-1 and 6Pgdh-3 is thus composed of subunits that differ in length by approximately 15 amino acid residues. Divergence in the length and primary subunit structure may account for the lower thermal stability of the intergenic heterodimer compared with the corresponding homodimers. A limited survey of other solanaceous plant species suggests that the duplication of cytosolic 6PGDH-coding genes found in tomato may be widespread in the family.This is journal article 1145, Agricultural Experiment Station, New Mexico State University. This research was supported by USDA Grant 82-CRCR-1-1014 to S. D. Tanksley. We acknowledge the technical support of Jaime Iglesias and Fernando Loiaza.     

Characterization of two HMW glutenin subunit genes from Taenitherum Nevski

The compositions of high molecular weight (HMW) glutenin subunits from three species of Taenitherum Nevski (TaTa, 2n = 2x = 14), Ta. caput-medusae, Ta. crinitum and Ta. asperum, were investigated by SDS-PAGE analysis. The electrophoresis mobility of the x-type HMW glutenin subunits were slower or equal to that of wheat HMW glutenin subunit Dx2, and the electrophoresis mobility of the y-type subunits were faster than that of wheat HMW glutenin subunit Dy12. Two HMW glutenin genes, designated as Tax and Tay, were isolated from Ta. crinitum, and their complete nucleotide coding sequences were determined. Sequencing and multiple sequences alignment suggested that the HMW glutenin subunits derived from Ta. crinitum had the similar structures to the HMW glutenin subunits from wheat and related species with a signal peptide, and N- and C-conservative domains flanking by a repetitive domain consisted of the repeated short peptide motifs. However, the encoding sequences of Tax and Tay had some novel modification compared with the HMW glutenin genes reported so far: (1) A short peptide with the consensus sequences of KGGSFYP, which was observed in the N-terminal of all known HMW glutenin genes, was absent in Tax; (2) There is a specified short peptide tandem of tripeptide, hexapeptide and nonapeptide and three tandem of tripeptide in the repetitive domain of Tax; (3) The amino acid residues number is 105 (an extra Q presented) but not 104 in the N-terminal of Tay, which was similar to most of y-type HMW glutenin genes from Elytrigia elongata and Crithopsis delileana. Phylogenetic analysis indicated that Tax subunit was mostly related to Ax1, Cx, Ux and Dx5, and Tay was more related to Ay, Cy and Ry.     

Isolation and characterization of cytoplasmic and chloroplastic ribosomes and their ribosomal RNAs from the diatom Cylindrotheca fusiformis

The cytoplasmic and chloroplast ribosomes from the marine diatom Cylindrotheca fusiformis were isolated and characterized. The cytoplasmic ribosomes sedimented in sucrose at 84S and dissociated into subunits of 64S and 42S in the absence of Mg²⁺. It contained ribosomal RNAs with molecular weights of 1.31×10⁶ and 0.70×10⁶. The chloroplast ribosomes sedimented at 70S only in the presence of high Mg²⁺ concentrations (25–100 mM). No stable subunits were routinely observed and at very high levels of Mg²⁺ (>100 mM) the 70S species was converted to a form sedimenting at 55S. At 4°C ribosomal RNAs with molecular weights of 1.1×10⁶ and 0.40×10⁶ were detected on polyacrylamide gel electrophoresis. When the RNAs were resolved at room temperature the large molecular weight component disappeared while RNA with molecular weights of 0.65×10⁶ and 0.53×10⁶ were observed. Apparently the large chloroplast RNAs dissociated into two pieces of unequal molecular weight. These properties of the diatom's chloroplast ribosomes are very similar to those of the counter parts in unicellular green algae, which suggests that both types of algae have a common phylogenetic ancestor.     

Molecular heterogeneity and genetics of Vicia faba seed storage proteins

Summary Legumin and vicilin were purified from seeds of Vicia faba L. var. Scuro, characterized in different electrophoretic systems, and used to produce polyclonal antibodies in rabbits. Two-dimensional electrophoretic studies showed a wide range of heterogeneity in the subunits of both legumin and vicilin. Legumin was found to be composed of 29 disulphide-linked subunit pairs with different molecular weight and/or isoelectric point. Western blot analysis of legumin of several mutants revealed molecular polymorphism based on a corresponding gene family. Three different -major legumin patterns were found, and inheritance studies showed that the 34.3-kD legumin polypeptide is the product of one locus, Lg-1, which is the first legumin genetic locus described in Vicia faba. Vicilin was found to be composed of as many as 59 subunits distributed in a molecular weight range of 65.7 to 42.8 kD (major polypeptides) and 37.2 to 15.2 kD (minor polypeptides), with different isoelectric points. A model is proposed that explains the possible formation of the minor subunits and the major subunits of 48.2 and 46 kD molecular weight (MW) from proteolytic cleavages and/or glycosilation of precursor polypeptides. Ten different vicilin electrophoretic patterns were observed among the analyzed accessions, which showed large molecular polymorphism that proved to be under genetic control.Contribution no. 55 from the Center of Vegetable Breeding, Portici, Italy     

A cDNA clone from barley encoding the precursor from the photosystem I polypeptide PSI-G: Sequence similarity to PSI-K

A cDNA clone encoding the photosystem I subunit, PSI-G was isolated from barley using an oligonucleotide specifying a partial amino acid sequence from a 9 kDa polypeptide of barley photosystem I. The 724 bp sequence contains an open reading frame encoding a precursor polypeptide of 15 107 kDa. Import studies using the in vitro expressed barley PsaG cDNA clone demonstrate that PSI-G migrates with an apparent molecular mass of 9 kDa on SDS-polyacrylamide gels together with PSI-C (subunit-VII). The previous assignment of the gene product of PsaG from spinach as subunit V (Steppuhn J, Hermans J, Nechushtai R, Ljungberg U, Thümmler F, Lottspeich F, Herrmann RG, FEBS Lett 237: 218–224, 1988) needs to be re-examined. The expression of the psaG gene is light-induced similar to other barley photosystem I genes. A significant sequence similarity to PSI-K from Chlamydomonas reinhardtii was discovered when a gene database was searched with the barley PSI-G amino acid sequence. Extensive sequence similarity between the nuclear-encoded photosystem I subunits has not previously been found. The observed sequence similarity between PSI-G and PSI-K suggests a symmetric location of these subunits in the photosystem I complex. The hydropathy plot of the barley PSI-G polypeptide indicates two membrane-spanning regions which are also found at the corresponding locations in the PSI-K polypeptide. PSI-G and PSI-K probably have evolved from a gene duplication of an ancestral gene.     

Structural homology of endosperm high molecular weight glutenin subunits of common wheat (Triticum aestivum L.)

Summary Several high molecular weight endosperm glutenin subunits, coded by genes located on chromosomes 1A, 1B and 1D of common wheat, Triticum aestivum L. em. Thell., were isolated from excised gel segments and subjected to amino acid analysis and peptide mapping; the latter was carried out following a limited digestion with trypsin, chymotrypsin or Staphylococcus aureus — V8 protease. Generally, all high molecular weight glutenins had a similar amino acid composition but several significant differences were observed in some of them. Both analyses revealed that the structural similarity among the various subunits was related to the homology of the genes coding them: subunits coded by homoalleles, i.e., different alleles of the same gene, were most similar; those coded by homoeoalleles, i.e., alleles of homoeologous genes, were less similar; whereas subunits coded either by alleles of different genes of the same gene cluster, or by nonhomoeoalleles of homoeologous clusters, were the least similar. Several small peptides derived from protease digestion of various subunits had a higher than expected staining intensity indicating that small peptide repeats may be interspersed within the glutenin subunits. The evolutionary course of the high molecular weight glutenins is discussed.     

Isolation and characterization of the two structural genes coding for phosphofructokinase in yeast

Summary Yeast phosphofructokinase is an octamer composed of two different kinds of subunit. The genes coding for these subunits have been isolated by means of functional complementation in a pfk1 pfk2 double mutant. As a source of DNA the genomic library of Nasmyth and Tatchell (1980) constructed in the yeast multicopy vector YEp13 was used. Plasmids containing the information of one or the other gene were identified by back-transformation into pfk single mutants (pfk1 PFK2, PFK1 pfk2). Restriction maps of the respective insertions are provided. The genomic organization was confirmed by Southern analysis. Northern analysis showed hybridization to mRNAs of about 3.6 kb for both genes, corresponding to the molecular weight of the protein subunits. Transformation with one of the plasmids did not lead to an increase in phosphofructokinase activity. Subcloning of both genes in one multicopy vector (YEp13) and reintroduction into the yeast cell resulted in a 3.5-fold higher specific activity compared to the wild type. Overproduction of the protein subunits in this transformant was confirmed by SDS-polyacrylamide electrophoresis of crude extracts stained with Coomassie-blue. This was not accompanied by an increased ethanol production. The sequences encoding the two subunits were shown to share homology.     

Chloroplast-encoded small subunits of the three multiprotein complexes in photosynthetic electron transport

The photosystem I, photosystem II, and cytochromeb ₆ f complexes that are involved in electron transport of oxygenic photosynthesis consist of a number of subunits encoded by either the chloroplast or nuclear genomes. In addition to the major subunits that carry redox components or photosynthetic pigments, these complexes contain several to more than ten subunits with molecular masses of less than 10 kDa. Directed mutagenesis has served as a powerful tool for investigation of the roles of these small subunits in the organization or function of the complexes. Various chloroplast transformants of the green algaChlamydomonas reinhardtii and mutants of cyanobacteria in which a gene encoding a small subunit was deleted or altered have been constructed. Evidence has accumulated suggesting that these small subunits function in the assembly, stabilization, or protection from photoinhibition of the complexes or in the modulation or regulation of electron transport. This article presents an overview of the properties and functions of the chloroplast-encoded small subunits of the three multiprotein complexes of photosynthetic electron transport that have been mainly analyzed with chloroplast transformants ofC. reinhardtii and the corresponding cyanobacterial transformants. Recipient of the Botanical Society Award for Young Scientists, 1995.     

Phosphoglucose isomerase gene duplication in the bony fishes: An evolutionary history

Electrophoretic patterns of phosphoglucose isomerase (PGI) in bony fishes provide strong evidence for a model of genetic control by two independent structural gene loci, most likely resulting from a gene duplication. This model is confirmed by a comparison of certain kinetic and molecular properties of the PGI homodimers (PGI-1 and PGI-2) isolated from extracts of the teleost Astyanax mexicanus. In addition, in most higher teleosts examined, the PGI enzymes show a regular pattern of tissue distribution, with PGI-2 predominant in muscle, the heterodimer often strongest in the heart, and PGI-1 predominant in liver and other organs. An examination of 53 species of bony fishes belonging to 38 families indicates a widespread occurrence of duplicate PGI loci and an early origin of the gene duplication, perhaps in the Leptolepiformes. The apparent presence of three PGI loci in trout and goldfish exemplifies how new loci can be incorporated into the genome through polyploidization.This research was supported in part by a NSF graduate traineeship to J.C.A., by the Clayton Foundation for Research in Biochemistry (G.B.K.), by NSF Grant GB-15644 and NIH Grant GM-15769 to Robert K. Selander, and by contract AT(38-1)-310 between the University of Georgia and the U.S. Atomic Energy Commission.     

Superoxide dismutase from Mycobacterium species,strain Takeo

Superoxide dismutase from Mycobacterium species, strain Takeo, has been purified to homogeneity as judged by disc gel electrophoresis and ultracentrifugation. The enzyme was found to have a molecular weight of approximately 61 500 by sedimentation equilibrium and to contain manganese by atomic absorption and electron spin resonance spectra. The amino acid composition was also determined. The enzyme was considerably stable to the treatment with sodium dodecyl sulfate; unless incubating at 80°C for 2 min, it was not completely dissociated into the subunits. The molecular weight of the subunit was found to be approximately 21 000. Antibodies against the superoxide dismutase were produced by immunization of rabbits with the enzyme, and the -globulin fraction was purified. Superoxide dismutase preparations obtained from various species of mycobacteria and nocardia cross-reacted to different degrees with these antibodies on the Ouchterlony double diffusion plates. Comparative immunological studies indicated that strain Takeo might be most closely related to Myobacterium smegmatis among species of mycobacteria and nocardia tested. The antibodies against superoxide dismutase may be used as a valuable tool for the classification of mycobacteria.     

High molecular weight glutenin subunit in durum wheat (T. durum)

Summary The diversity of high molecular weight (HMW) glutenin subunits of 502 varieties of durum wheat (Triticum durum) from 23 countries was studied using sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE). Twenty-nine types of patterns were observed with 18 mobility bands. A total of 18 alleles were identified by comparing the mobilities of their subunits to those previously found in hexaploid wheat (T. aestivum) and in Triticum turgidum var. dicoccum. Five new alleles were detected: two on the Glu A1 and three on the Glu B1 locus. Comparison of the frequency of alleles in the three species T. aestivum, T. dicoccum and T. durum was investigated. Significant differences exist between each of these species on the basis of the frequency distributions of their three and four common alleles at the Glu A1 and Glu B1 locus, respectively. The Glu B1c allele occuring very frequently in hexaploid wheats was not found in the two tetraploid species. More than 83% of the T. durum analysed were found to have the Glu A1c (null) allele.