Jürgen Kroymann

Biosynthesis of methionine-derived glucosinolates in Arabidopsis thaliana: recombinant expression and characterization of methylthioalkylmalate synthase, the condensing enzyme of the chain-elongation cycle

The major class of glucosinolates in Arabidopsis thaliana (L.) Heynh. are biosynthesized from methionine involving a three-step chain-elongation cycle. Each passage through the cycle results in the net addition of a single methylene group, with up to six cycles of elongation occurring in A. thaliana. The first reaction of the cycle is catalyzed by a methylthioalkylmalate synthase (MAMS), which condenses a ω-methylthio-2-oxoalkanoic acid with acetyl-CoA. Here we have demonstrated that MAM1, one of two similar genes in the A. thaliana ecotype Columbia, encodes a MAMS catalyzing the condensing reactions of the first two elongation cycles but not those of further cycles. The Columbia ecotype is dominated by compounds that have undergone only two elongation cycles. The A. thaliana MAM1 protein exhibits basic sequence similarity to other previously described enzymes catalyzing the condensation of 2-oxo acids and acetyl-CoA, such as isopropylmalate synthase (EC 2.3.3.13), an enzyme of leucine biosynthesis, and homocitrate synthase (EC 2.3.3.14). It also shares similar properties with them, including the catalytic requirements for a divalent metal ion and an adenine nucleotide. However, the MAM1 protein does not show activity with the substrates of any of these other enzymes, and was chromatographically separable from isopropylmalate synthase in extracts of A. thaliana. Thus, MAM1 is exclusively an enzyme of secondary metabolism, distinct from primary metabolic enzymes catalyzing similar reactions.

α-Keto acid elongation and glucosinolate biosynthesis in Arabidopsis thaliana

Abstract QTL mapping of glucosinolates in a RI population derived from an F1 hybrid between the Arabidopsis thaliana ecotypes Columbia and Landsberg erecta identified a single major QTL coincident with the GSL-ELONG locus which regulates side chain elongation. Physical mapping and sequencing identified two members of an isopropylmalate synthase-like gene family within the region of maximum LOD score for the QTL and the GSL-ELONG non-recombinant region. These genes are prime candidates for regulating glucosinolate biosynthesis.

The mitochondrial genome of Chlorogonium elongatum inferred from the complete sequence

Abstract. The 22,704-bp circular mitochondrial DNA (mtDNA) of the chlamydomonad alga Chlorogonium elongatum was completely cloned and sequenced. The genome encodes seven proteins of the respiratory electron transport chain, subunit 1 of the cytochrome oxidase complex (cox1), apocytochrome b (cob), five subunits of the NADH dehydrogenase complex (nad1, nad2, nad4, nad5, and nad6), a set of three tRNAs (Q, W, M), and the large (LSU)- and small (SSU)-subunit ribosomal RNAs. Six group-I introns were found, two each in the cox1, cob, and nad5 genes. In each intron an open reading frame (ORF) related to maturases or endonucleases was identified. Both the LSU and the SSU rRNA genes are split into fragments intermingled with each other and with other genes. Although the average A + T content is 62.2%, GC-rich clusters were detected in intergenic regions, in variable domains of the rRNA genes, and in introns and intron-encoded ORFs. A comparison of the genome maps reveals that C. elongatum and Chlamydomonas eugametos mtDNAs are more closely related to one another than either is to Chlamydomonas reinhardtii mtDNA.

The shrunken genome of Arabidopsis thaliana

This paper examines macro and micro-level patterns of genome size evolution in the Brassicaceae. A phylogeny of 25 relatives of Arabidopsis thaliana was reconstructed using four molecular markers under both parsimony and Bayesian methods. Reconstruction of genome size (C value) evolution as a discrete character and as a continuous character was also performed. In addition, size dynamics in small chromosomal regions were assessed by comparing genomic clones generated for Arabidopsis lyrata and for Boechera stricta to the fully sequenced genome of A. thaliana. The results reveal a sevenfold variation in genome size among the taxa investigated and that the small genome size of A. thaliana is derived. Our results also indicate that the genome is free to increase or decrease in size across these evolutionary lineages without a directional bias. These changes are accomplished by insertions and deletions at both large and small-scales occurring mostly in intergenic regions, with repetitive sequences and transposable elements implicated in genome size increases. The focus upon taxa relatively closely related to the model organism A. thaliana, and the combination of complementary approaches, allows for unique insights into the processes driving genome size changes.

THE APOCYTOCHROME-B GENE IN CHLOROGONIUM ELONGATUM (CHLAMYDOMONADACEAE) : AN INTRONIC GIY-YIG ORF IN GREEN ALGAL MITOCHONDRIA

Abstract The mitochondrial cob gene from the green alga Chlorogonium elongatum (Chlamydomonadaceae) is interrupted by two group-I introns each containing an open reading frame in-phase with the upstream exon. One of these ORFs belongs to the LAGLI-DADG family, the other to the GIY-YIG family. The latter has not yet been identified in any mitochondrial genome except those from fungi. The Chlorogonium ORFs are similar to ORFs encoded by fungal introns that are located at an identical position within the gene, and to the ORF encoded by the mobile intron in the Chlamydomonas smithii cob gene.

Opposite Regulation of the Copy Number and the Expression of Plastid and Mitochondrial Genes by Light and Acetate in the Green Flagellate Chlorogonium

In the unicellular green alga Chlorogonium elongatum (Chlamydomonadaceae), the formation of both the photosynthetic and the respiratory apparatus is under the control of light and acetate. Autotrophically cultured cells possess a 3-fold higher copy number of the plastid genes rbcL and psbA than cells cultivated in the dark with acetate (heterotrophic cells). Under mixotrophic conditions (light and acetate), both genes are present at an intermediate level. This pattern is repeated at the mRNA level. The amounts of rbcL and psbA mRNAs are approximately 3-fold higher in autotrophic cells than in heterotrophic ones and are intermediate in mixotrophic cells. As expected, the copy number of the nuclear-encoded rbcS gene is constant irrespective of the applied culture conditions. RbcS mRNA, however, is 7-fold more frequent in autotrophic than in heterotrophic cells. Again, mixotrophic cells show an intermediate level. In contrast to genes encoding plastid proteins, the copy number and transcript level of the mitochondrial cob gene are approximately 5-fold higher in heterotrophic cells than in autotrophic ones. As before, mixotrophic cells take an intermediate position. Therefore, light and acetate control the genes involved in the formation of either the photosynthetic or the respiratory apparatus in a coordinated but opposite manner.