Gerd Haberhausen

Functional loss of all ndh genes in an otherwise relatively unaltered plastid genome of the holoparasitic flowering plant Cuscuta reflexa

We have cloned and sequenced an area of about 9.0 kb of the plastid DNA (ptDNA) from the holoparasitic flowering plant Cuscuta reflexa to investigate the evolutionary response of plastid genes to a reduced selective pressure. The region contains genes for the 16S rRNA, a subunit of a plastid NAD(P)H dehydrogenase (ndhB), three transfer RNAs (trnA, trnI, trnV) as well as the gene coding for the ribosomal protein S7 (rps7). While the other genes are strongly conserved in C. reflexa, the ndhB gene is a pseudogene due to many frameshift mutations. In addition we used heterologous gene probes to identify the other ndh genes encoded by the plastid genome in higher plants. No hybridization signals could be obtained, suggesting that these genes are either lost or strongly altered in the ptDNA of C. reflexa. Together with evidence of deleted genes in the ptDNA of C. reflexa, the plastid genome can be grouped into four classes reflecting a different evolutionary rate in each case. The phylogenetic position of Cuscuta and the significance of ndh genes in the plastid genome of higher plants are discussed.

Organization and sequence of photosynthetic genes from the plastid genome of the holoparasitic flowering plant Cuscuta reflexa.

SummaryWe have cloned and sequenced an area of about 6 kb of the plastid DNA (ptDNA) from the holoparasitic plant Cuscuta refexa. This region contains (in the following order) genes for the cytochrome b6/f-complex subunit V (petG), tRNAVal (trnV), tRNAMet (trnM), the ε and β-subunit of the chloroplast ATP-synthase (atpE and atpB) and the large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase (Rubisco; rbcL). In addition we identified other photosynthesis-related genes (atpA, petB, psaA, psbA, psbB, psbC, and psbD) in C. refexa by heterologous hybridization. The gene arrangement of the sequenced area is, except for the petG gene, the same as in ptDNAs of other higher plants (e.g. Nicotiana tabacum). Sequence homologies between the Cuscuta genes and corresponding genes from higher plants are in the range of 90%. The only significant difference is that the rbcL gene of C. refexa encodes a polypeptide which is 18–23 amino acids longer than in other higher plants. This is remarkable since C. refexa has lost its ability to grow photoautotrophically. The transcript level of the rbcL gene, however, is strongly reduced as compared to tobacco. These findings are compatible with results from Western blotting analysis, where no Rubisco large subunit was detectable, and with the lack of Rubisco activity in crude extracts of C. ref lexa.

A large deletion in the plastid DNA of the holoparasitic flowering plant Cuscuta reflexa concerning two ribosomal proteins (rpl2, rpl23), one transfer RNA (trnI) and an ORF 2280 homologue.

We have determined the nucleotide sequence of a 5.3-kb region of the plastid DNA (ptDNA) from the heterotrophic holoparasitic plant Cuscuta reflexa. The cloned area contains genes for the D1-protein (32-kDa protein; psbA), tRNAHis (trnH), ORF 740 (homologous to ORF 2280 from Nicotiana tabacum), ORF 77 (homologous to ORF 70), tRNALeu (trnL) and a hypothetical ORF 55 which has no homology to any known gene among higher plants. This 5.3-kb area is colinear with a 12.4-kb region of tobacco ptDNA and has therefore undergone several deletions totalling 7.1 kb. Most of the missing nucleotides belong to one large deletion in the ptDNA of C. reflexa of approximately 6.5 kb. This deletion involves two ribosomal protein genes, rpl2 and rpl23, as well as the transfer RNA for Isoleucin (trnI) and a region encoding 1540 amino-acid residues of an ORF 2280 homologue, as compared to tobacco chloroplast DNA. This is remarkable since the remaining genes, especially the psbA gene, are highly conserved in C. reflexa. Furthermore, we found that the expression of the psbA gene is in the same range as in the autotrophic Ipomoea purpurea which belongs to the same family as Cuscuta (Convolvulaceae). Here we hypothesize a total loss of rpl2 and rpl23 in the entire genome of C. reflexa. The phylogenetic position of, and the evolutionary change of ptDNA from, Cuscuta are discussed.

Spinocerebellar ataxia, type 3 (SCA3) is genetically identical to Machado-Joseph disease (MJD)

Spinocerebellar ataxia, type 3 (SCA3) and Machado-Joseph disease (MJD) are two clinically distinct representatives of the heterogeneous group of autosomal dominant cerebellar ataxias. Assignment of the disease genes to the same region of the long arm of chromosome 14 in both SCA3 and MJD suggested that these two disorders are genetically identical. The recent identification of a trinucleotide (CAG) repeat expansion in a gene underlying MJD facilitates assessment of this hypothesis. We analysed the MJD gene in members of a family with characteristic features of SCA3 and no symptoms typical of MJD. We found the same trinucleotide repeat expansion within the gene that was previously described in patients with MJD. The findings demonstrate that SCA3 and MJD are genetically identical in spite of their pronounced clinical differences. Furthermore, we demonstrate a striking variation in the copy number of the CAG repeat among affected members of the same family.

AFX1 and p54nrb: fine mapping, genomic structure, and exclusion as candidate genes of X-linked dystonia parkinsonism.

Abstract We have mapped AFX1 and p54nrb to a yeast artificial chromosome (YAC) contig of Xq13.1 that harbors the X-linked dystonia parkinsonism (XDP) locus DYT3. AFX1 is flanked by loci DXS7116 and Il2Rγ, and p54nrb by loci DXS6673E and DXS7120. The exon-intron structure of both genes was analyzed. AFX1 is composed of three exons with most of exon 3 being untranslated. p54nrb is made up of 12 exons ranging in size from 40 bp to 1227 bp. The start codon is in exon 3 and the stop codon in exon 12. Both genes are expressed in the brain, among other tissues. AFX1 and p54nrb were excluded as candidates of DYT3 by sequencing of the exons and the flanking intronic sequences in an XDP patient and a control, and by Northern blot analysis.