Cadaverine regulates biotin synthesis to modulate primary root growth in Arabidopsis

Cadaverine, a polyamine, has been linked to modification of root growth architecture and response to environmental stresses in plants. However, the molecular mechanisms that govern the regulation of root growth by cadaverine are largely unexplored. Here we conducted a forward genetic screen and isolated a mutation, cadaverine hypersensitive 3 (cdh3), which resulted in increased root-growth sensitivity to cadaverine, but not other polyamines. This mutation affects the BIO3-BIO1 biotin biosynthesis gene. Exogenous supply of biotin and a pathway intermediate downstream of BIO1, 7,8-diaminopelargonic acid, suppressed this cadaverine sensitivity phenotype. An in vitro enzyme assay showed cadaverine inhibits the BIO3-BIO1 activity. Furthermore, cadaverine-treated seedlings displayed reduced biotinylation of Biotin Carboxyl Carrier Protein 1 of the acetyl-coenzyme A carboxylase complex involved in de novo fatty acid biosynthesis, resulting in decreased accumulation of triacylglycerides. Taken together, these results revealed an unexpected role of cadaverine in the regulation of biotin biosynthesis, which leads to modulation of primary root growth of plants.     

An embryo-lethal mutant of Arabidopsis thaliana is a biotin auxotroph

Lethal mutants have been used in a variety of animal systems to study the genetic control of morphogenesis and differentiation. Abnormal development has been shown in some cases to be caused by defects in basic cellular processes. We describe in this report an embryo-lethal mutant of Arabidopsis thaliana that can be rescued by the addition of biotin to arrested embryos cultured in vitro and to mutant plants grown in soil. Mutant plants rescued in culture produced phenotypically normal seeds when supplemented with biotin but became chlorotic and failed to produce fertile flowers in the absence of biotin. Arrested embryos were also rescued by desthiobiotin, the immediate precursor of biotin in bacteria. Langridge proposed 30 years ago (1958, Aust. J. Biol. Sci. 11, 58-68) that the scarcity of plant auxotrophs might be caused by lethality prior to germination. The bio1 mutant of Arabidopsis described in this report clearly demonstrates that some auxotrophs in higher plants are eliminated through embryonic lethality. Further analysis of this mutant should provide valuable information on the nature of plant auxotrophs, the biosynthesis and utilization of biotin in plants, and the underlying causes of developmental arrest in lethal mutants of Arabidopsis.     

The reacquisition of biotin prototrophy in Saccharomyces cerevisiae involved horizontal gene transfer, gene duplication and gene clustering

The synthesis of biotin, a vitamin required for many carboxylation reactions, is a variable trait in Saccharomyces cerevisiae. Many S. cerevisiae strains, including common laboratory strains, contain only a partial biotin synthesis pathway. We here report the identification of the first step necessary for the biotin synthesis pathway in S. cerevisiae. The biotin auxotroph strain S288c was able to grow on media lacking biotin when BIO1 and the known biotin synthesis gene BIO6 were introduced together on a plasmid vector. BIO1 is a paralog of YJR154W, a gene of unknown function and adjacent to BIO6. The nature of BIO1 illuminates the remarkable evolutionary history of the biotin biosynthesis pathway in S. cerevisiae. This pathway appears to have been lost in an ancestor of S. cerevisiae and subsequently rebuilt by a combination of horizontal gene transfer and gene duplication followed by neofunctionalization. Unusually, for S. cerevisiae, most of the genes required for biotin synthesis in S. cerevisiae are grouped in two subtelomeric gene clusters. The BIO1-BIO6 functional cluster is an example of a cluster of genes of "dispensable function," one of the few categories of genes in S. cerevisiae that are positionally clustered.     

An Embryo-Defective Mutant of Arabidopsis Disrupted in the Final Step of Biotin Synthesis

Auxotrophic mutants have played an important role in the genetic dissection of biosynthetic pathways in microorganisms. Equivalent mutants have been more difficult to identify in plants. The bio1 auxotroph of Arabidopsis thaliana was shown previously to be defective in the synthesis of the biotin precursor 7,8-diaminopelargonic acid. A second biotin auxotroph of A. thaliana has now been identified. Arrested embryos from this bio2 mutant are defective in the final step of biotin synthesis, the conversion of dethiobiotin to biotin. This enzymatic reaction, catalyzed by the bioB product (biotin synthase) in Escherichia coli, has been studied extensively in plants and bacteria because it involves the unusual addition of sulfur to form a thiophene ring. Three lines of evidence indicate that bio2 is defective in biotin synthase production: mutant embryos are rescued by biotin but not dethiobiotin, the mutant allele maps to the same chromosomal location as the cloned biotin synthase gene, and gel-blot hybridizations and polymerase chain reaction amplifications revealed that homozygous mutant plants contain a deletion spanning the entire BIO2-coding region. Here we describe how the isolation and characterization of this null allele have provided valuable insights into biotin synthesis, auxotrophy, and gene redundancy in plants.     

Arrested Embryos from the bio1 Auxotroph of Arabidopsis thaliana Contain Reduced Levels of Biotin

The bio1 auxotroph of Arabidopsis thaliana is a recessive embryonic lethal that forms normal plants in the presence of biotin. The purpose of this study was to determine whether aborted seeds produced by heterozygous plants grown without vitamin supplements contained reduced levels of biotin. Two methods were used to determine the biotin content of mutant and wild-type tissues: streptavidin binding in microtiter plates and growth of the biotin-requiring bacterium Lactobacillus plantarum. Total biotin was measured in extracts prepared from immature seeds prior to desiccation. Aborted seeds produced by heterozygous (bio1/BIO1) plants contained some biotin in the maternal seed coat but virtually no detectable biotin in the arrested embryo. This lack of biotin was not observed in arrested embryos from other mutants with similar patterns of abnormal development. These results are consistent with the model that bio1 tissues are defective in biotin synthesis. The alternative model of increased degradation is inconsistent with the recessive nature of the mutation and the ability of rescued plants to continue growing for several weeks following removal of supplemental biotin.     

The plant biotin synthase reaction. Identification and characterization of essential mitochondrial accessory protein components

In plants, the last step of the biotin biosynthetic pathway is localized in mitochondria. This chemically complex reaction is catalyzed by the biotin synthase protein, encoded by the bio2 gene in Arabidopsis thaliana. Unidentified mitochondrial proteins in addition to the bio2 gene product are obligatory for the reaction to occur. In order to identify these additional proteins, potato mitochondrial matrix was fractionated onto different successive chromatographic columns. Combination experiments using purified Bio2 protein and the resulting mitochondrial matrix subfractions together with a genomic based research allowed us to identify mitochondrial adrenodoxin, adrenodoxin reductase, and cysteine desulfurase (Nfs1) proteins as essential components for the plant biotin synthase reaction. Arabidopsis cDNAs encoding these proteins were cloned, and the corresponding proteins were expressed in Escherichia coli cells and purified. Purified recombinant adrenodoxin and adrenodoxin reductase proteins formed in vitro an efficient low potential electron transfer chain that interacted with the bio2 gene product to reconstitute a functional plant biotin synthase complex. Bio2 from Arabidopsis is the first identified protein partner for this specific plant mitochondrial redox chain.     

Mutants of Escherichia coli Defective in Membrane Phospholipid Synthesis: Mapping of sn-Glycerol 3-Phosphate Acyltransferase Km Mutants

plsB mutants of Escherichia coli are sn-glycerol 3-phosphate auxotrophs which owe their requirement to a K(m) defect in sn-glycerol 3-phosphate acyltransferase, the first enzyme in the phospholipid biosynthetic pathway. We have located the plsB gene at minute 69 of the E. coli genetic map, far removed from the gene defined by mutants with a temperature-sensitive sn-glycerol 3-phosphate acyltransferase. The plsB gene was cotransduced with the dctA locus, and the transduction data indicated that the clockwise gene order is asd, plsB, dctA, xyl. plsB(-) is recessive to plsB(+) and all acyltransferase K(m) mutants tested lie very close to the plsB locus. Effective supplementation of plsB mutants was shown not to require a defective glpD gene.     

Characterization of the biotin biosynthesis pathway in Saccharomyces cerevisiae and evidence for a cluster containing BIO5, a novel gene involved in vitamer uptake.

An engineered mutant of Saccharomyces cerevisiae affected in biotin biosynthesis has been isolated. This mutant allowed the characterization of a bio cluster (BIO3-4-5). We demonstrate that BIO3 (YNR058w) and BIO4 (YNR057c) encode, respectively, a 7, 8-diaminopelargonic acid aminotransferase and a dethiobiotin synthase, involved in the biotin biosynthesis pathway. A novel gene, BIO5 (YNR056c), is present immediately downstream from BIO4. This gene encodes Bio5p, a protein with 11 putative transmembrane regions. Uptake experiments performed with labeled 7-keto 8-aminopelargonic acid indicate that Bio5p is responsible for transport into the cell of 7-keto 8-aminopelargonic acid.     

An Allelic Series of Blue Fluorescent Trp1 Mutants of Arabidopsis Thaliana

Nine blue fluorescent mutants of the flowering plant Arabidopsis thaliana were isolated by genetic selections and fluorescence screens. Each was shown to contain a recessive allele of trp1, a previously described locus that encodes the tryptophan biosynthetic enzyme phosphoribosylanthranilate transferase (PAT, called trpD in bacteria). The trp1 mutants consist of two groups, tryptophan auxotrophs and prototrophs, that differ significantly in growth rate, morphology, and fertility. The trp1 alleles cause plants to accumulate varying amounts of blue fluorescent anthranilate compounds, and only the two least severely affected of the prototrophs have any detectable PAT enzyme activity. All four of the trp1 mutations that were sequenced are G to A or C to T transitions that cause an amino acid change, but in only three of these is the affected residue phylogenetically conserved. There is an unusually high degree of sequence divergence in the single-copy gene encoding PAT from the wild-type Columbia and Landsberg erecta ecotypes of Arabidopsis.     

Synthesis of Desthiobiotin from 7,8-Diaminopel-argonic Acid in Biotin Auxotrophs of Escherichia coli K-12

The synthesis of desthiobiotin from 7,8-diaminopelargonic acid (DAP) was demonstrated in resting cell suspensions of Escherichia coli K-12 bioA mutants under conditions in which the biotin locus was derepressed. The biosynthetically formed desthiobiotin was identified by chromatography, electrophoresis, and by its ability to support the growth of yeast and those E. coli biotin auxotrophs that are blocked earlier in the biotin pathway. Optimal conditions for desthiobiotin synthesis were determined. Desthiobiotin synthetase activity was repressed 67% when partially derepressed resting cells were incubated in the presence of 3 ng of biotin per ml. Serine, bicarbonate, and glucose stimulated desthiobiotin synthesis apparently by acting as sources of CO(2). The results of this study are consistent with an earlier postulated pathway for biotin biosynthesis in E. coli: pimelic acid --> 7-oxo-8-aminopelargonic acid --> DAP --> desthiobiotin --> biotin.     

Genetic and biochemical analysis of the biotin loci of Escherichia coli K-12

Some 60 biotin auxotrophs of Escherichia coli K-12 were isolated and classified into four groups according to their cross-feeding patterns, excertion products, and their ability to show a growth response to various biotin vitamers. Since all the mutants could be transduced with lambdadbio phages known to carry the entire bioA locus, it was concluded that all of the mutation sites were located in this locus. It was also possible to derive a gene order for the different mutant groups on the basis of transduction studies with various lambdadbio phages that carry portions of the bioA locus. A possible biochemical pathway for the biosynthesis of biotin in E. coli K-12 is discussed.     

Complementation of anArabidopsis thaliana biotin auxotroph with anEscherichia coli biotin biosynthetic gene

TheArabidopsis thaliana biotin auxotrophbio1 was rendered prototrophic by transformation with a chimeric transgene containing theEscherichia coli bioA gene driven by a constitutive promoter. ThebioA gene encodes the biotin biosynthetic enzyme 7,8-diaminopelargonic acid aminotransferase. Unlike the untransformed control plants, transgenic plants expressing the bacterial transgene synthesized biotin and grew to maturity without biotin-deficiency symptoms. These findings demonstrate thatbio1/bio1 mutant plants are defective in the gene encoding 7,8-diaminopelargonic acid aminotransferase.     

Complementation of anArabidopsis thaliana biotin auxotroph with anEscherichia coli biotin biosynthetic gene

TheArabidopsis thaliana biotin auxotrophbio1 was rendered prototrophic by transformation with a chimeric transgene containing theEscherichia coli bioA gene driven by a constitutive promoter. ThebioA gene encodes the biotin biosynthetic enzyme 7,8-diaminopelargonic acid aminotransferase. Unlike the untransformed control plants, transgenic plants expressing the bacterial transgene synthesized biotin and grew to maturity without biotin-deficiency symptoms. These findings demonstrate thatbio1/bio1 mutant plants are defective in the gene encoding 7,8-diaminopelargonic acid aminotransferase.     

The ISC [corrected] proteins Isa1 and Isa2 are required for the function but not for the de novo synthesis of the Fe/S clusters of biotin synthase in Saccharomyces cerevisiae

The yeast Saccharomyces cerevisiae is able to use some biotin precursors for biotin biosynthesis. Insertion of a sulfur atom into desthiobiotin, the final step in the biosynthetic pathway, is catalyzed by biotin synthase (Bio2). This mitochondrial protein contains two iron-sulfur (Fe/S) clusters that catalyze the reaction and are thought to act as a sulfur donor. To identify new components of biotin metabolism, we performed a genetic screen and found that Isa2, a mitochondrial protein involved in the formation of Fe/S proteins, is necessary for the conversion of desthiobiotin to biotin. Depletion of Isa2 or the related Isa1, however, did not prevent the de novo synthesis of any of the two Fe/S centers of Bio2. In contrast, Fe/S cluster assembly on Bio2 strongly depended on the Isu1 and Isu2 proteins. Both isa mutants contained low levels of Bio2. This phenotype was also found in other mutants impaired in mitochondrial Fe/S protein assembly and in wild-type cells grown under iron limitation. Low Bio2 levels, however, did not cause the inability of isa mutants to utilize desthiobiotin, since this defect was not cured by overexpression of BIO2. Thus, the Isa proteins are crucial for the in vivo function of biotin synthase but not for the de novo synthesis of its Fe/S clusters. Our data demonstrate that the Isa proteins are essential for the catalytic activity of Bio2 in vivo.     

N-acetyl-L-glutamate synthase of Neurospora crassa. Characteristics, localization, regulation, and genetic control

N-Acetylglutamate synthase, an early enzyme of the arginine pathway, provides acetylglutamate for ornithine synthesis in the so-called "acetylglutamate cycle." Because acetylglutamate is regenerated as ornithine is formed, the enzyme has only a catalytic or anaplerotic role in the pathway, maintaining "bound" acetyl groups during growth. We have detected this enzyme in crude extracts of Neurospora crassa and have localized it to the mitochondria along with other ornithine biosynthetic enzymes. The enzyme is bound to the mitochondrial membrane. The enzyme has a pH optimum of 9.0 and Km values for glutamate and CoASAc of 6.3 and 1.6 mM, respectively. It is feedback-inhibited by L-arginine (I0.5 = 0.16 mM), and its specific activity is augmented 2-3-fold by arginine starvation of the mycelium. Mutants of the newly recognized arg-14 locus lack activity for the enzyme. Because these mutants are complete auxotrophs, we conclude that N-acetylglutamate synthase is an indispensible enzyme of arginine biosynthesis in N. crassa. This work completes the assignment of enzymes of the arginine pathway of N. crassa to corresponding genetic loci. The membrane localization of the enzyme suggests a novel mechanism by which feedback inhibition might occur across a semipermeable membrane.     

Somatic cell genetics and the study of cholesterol metabolism

The regulation of cholesterol biosynthesis by extracellular cholesterol occurs both in whole animal tissue and in permanent somatic cell lines in culture. Permanent mammalian cells lines, under optimized growth conditions, are easily manipulated both biochemically and genetically. The Chinese hamster ovary cell line (CHO-K1) is the most widely used cell line for genetic studies. CHO-K1 is a pseudo-diploid mammalian cell exhibiting a short doubling time and a relatively high plating efficiency. Somatic cell mutants can be generated through mutagenesis and also by drug adaptation. Following mutagenesis, auxotrophs may be isolated either by selection or by screening. Most selection procedures for mutants of cholesterol metabolism must be done in serum depleted of cholesterol which requires the endogenous biosynthetic pathway to be intact. Mutants failing to produce cholesterol do not replicate their DNA and exhibit reduced concentrations of cholesterol in their membranes. BUdR and polyene antibiotics have both been used to select against the wild-type cells which incorporate these compounds and are killed, allowing the survival of the mutant cells. Both mevalonate and cholesterol auxotrophs have been isolated with the BUdR technique and have proven useful for elucidation of the early steps in cholesterol biosynthesis, particularly for the ratelimiting enzyme HMG-CoA reductase. Somatic cell fusion of a mutant and wild-type cell followed by chromosomal segregation, routinely used to map human genes, has also been used to map the human gene for HMG-CoA synthase. Such hybrids also provide valuable information on the dominance or recessivity of a specific lesion. DNA-mediated gene transfer into somatic cell mutants allows the selection of DNA sequences which complement the mutation, and is also useful for analysis of regions of regulatory significance. Mutants, resistant to the regulatory effects of oxygenated sterols, can be isolated following mutagenesis. Mutants of this type vary the lipid content of their membranes in response to cholesterol concentration in the medium. All such mutants tested exhibit a pleiotropic regulatory effect on more than one enzyme in the cholesterol biosynthetic pathway. Adaptation to drugs such as compactin and mevinolin, which inhibit HMG-CoA reductase, have been used to produce mutants which overexpress enzymes in the pathway. These amplified cells are useful sources of specific mRNAs for construction of cDNA libraries and gene isolation. Structure-function relationships of membrane sterols can be studied in cholesterol auxotrophs where changes in acyl-chain ordering can be manipulated by exogenous sterols in the medium.     

Toxicity of the pyrimidine biosynthetic pathway intermediate carbamyl aspartate in Salmonella typhimurium

Growth of Salmonella typhimurium pyrC or pyrD auxotrophs was severely inhibited in media that caused derepressed pyr gene expression. No such inhibition was observed with derepressed pyrA and pyrB auxotrophs. Growth inhibition was not due to the depletion of essential pyrimidine biosynthetic pathway intermediates or substrates. This result and the pattern of inhibition indicated that the accumulation of the pyrimidine biosynthetic pathway intermediate carbamyl aspartate was toxic. This intermediate is synthesized by the sequential action of the first two enzymes of the pathway encoded by pyrA and pyrB and is a substrate for the pyrC gene product. It should accumulate to high levels in pyrC or pyrD mutants when expression of the pyrA and pyrB genes is elevated. The introduction of either a pyrA or pyrB mutation into a pyrC strain eliminated the observed growth inhibition. Additionally, a direct correlation was shown between the severity of growth inhibition of a pyrC auxotroph and the levels of the enzymes that synthesize carbamyl aspartate. The mechanism of carbamyl aspartate toxicity was not identified, but many potential sites of growth inhibition were excluded. Carbamyl aspartate toxicity was shown to be useful as a phenotypic trait for classifying pyrimidine auxotrophs and may also be useful for positive selection of pyrA or pyrB mutants. Finally, we discuss ways of overcoming growth inhibition of pyrC and pyrD mutants under derepressing conditions.