Independent segregation of the plastid genome and cytoplasmic male sterility in Petunia somatic hybrids

Analysis of variation in chloroplast DNA sequences

This chapter introduces and reviews methods for analyzing variation in chloroplast DNA, mainly by polymerase chain reaction (PCR) and subsequent revelation of polymorphisms. Sources for chloroplast primers are discussed, as well as methods such as Sanger sequencing, PCR followed by restriction fragment length polymorphism (RFLP), gel electrophoresis, fragment analysis on automated DNA sequencers, denaturing high-performance liquid chromatography (dHPLC), and next-generation sequencing (NGS). A special section deals with peculiarities of chloroplast DNA variation, such as tandem repeats and mini- and microsatellites.

Exclusion of plastid nucleoids and ribosomes from stromules in tobacco and Arabidopsis

Stromules are stroma-filled tubules that extend from the surface of plastids and allow the transfer of proteins as large as 550 kDa between interconnected plastids. The aim of the present study was to determine if plastid DNA or plastid ribosomes are able to enter stromules, potentially permitting the transfer of genetic information between plastids. Plastid DNA and ribosomes were marked with green fluorescent protein (GFP) fusions to LacI, the lac repressor, which binds to lacO-related sequences in plastid DNA, and to plastid ribosomal proteins Rpl1 and Rps2, respectively. Fluorescence from GFP-LacI co-localised with plastid DNA in nucleoids in all tissues of transgenic tobacco (Nicotiana tabacum L.) examined and there was no indication of its presence in stromules, not even in hypocotyl epidermal cells, which contain abundant stromules. Fluorescence from Rpl1-GFP and Rps2-GFP was also observed in a punctate pattern in chloroplasts of tobacco and Arabidopsis [Arabidopsis thaliana (L.) Heynh.], and fluorescent stromules were not detected. Rpl1-GFP was shown to assemble into ribosomes and was co-localised with plastid DNA. In contrast, in hypocotyl epidermal cells of dark-grown Arabidopsis seedlings, fluorescence from Rpl1-GFP was more evenly distributed in plastids and was observed in stromules on a total of only four plastids (<0.02% of the plastids observed). These observations indicate that plastid DNA and plastid ribosomes do not routinely move into stromules in tobacco and Arabidopsis, and suggest that transfer of genetic information by this route is likely to be a very rare event, if it occurs at all.

Dynamic morphology of plastids and stromules in angiosperm plants

Labelling of plastids with fluorescent proteins has revealed the diversity of their sizes and shapes in different tissues of vascular plants. Stromules, stroma-filled tubules comprising thin extensions of the stroma surrounded by the double envelope membrane, have been observed to emanate from all major types of plastid, though less common on chloroplasts. In some tissue types, stromules are highly dynamic, forming, shrinking, attaching, releasing and fragmenting. Stromule formation is negatively affected by treatment of tissue with cytoskeletal inhibitors. Plastids can be connected by stromules, through which green fluorescent protein (GFP) and fluorescently tagged chloroplast protein complexes have been observed to flow. Within the highly viscous stroma, proteins traffic by diffusion as well as by an active process of directional travel, whose mechanism is unknown. In addition to exchanging materials between plastids, stromules may also serve to increase the surface area of the envelope for import and export, reduce diffusion distance between plastids and other organelles for exchange of materials, and anchor the plastid onto attachment points for proper positioning with the plant cell. Future studies should reveal how these functions may affect plants in adapting to the challenges of a changing environment.

The petunia restorer of fertility protein is part of a large mitochondrial complex that interacts with transcripts of the CMS-associated locus

A class of nuclear genes termed "restorers of fertility" (Rf) acts to suppress the expression of abnormal mitochondrial genes associated with cytoplasmic male sterility (CMS). In petunia, both the nuclear Rf gene and mitochondrial CMS-associated gene have previously been identified. The CMS-associated gene is an aberrant chimera in which portions of several mitochondrially encoded genes are fused to an unknown reading frame. The dominant Rf allele reduces the CMS-associated protein to nearly undetectable levels and alters the RNA population derived from the CMS locus, but its mechanism of action has not been determined. The petuniaRf gene is a member of the pentatricopeptide repeat gene family (PPR), an unusually large gene family in Arabidopsis (approximately 450 genes) compared with yeast (five genes) and mammalian genomes (six genes). The PPR gene family has been implicated in the control of organelle gene expression. To gain insight into the mode of action of PPR genes, we generated transgenic petunia plants expressing a functional tagged version of Rf. Analysis of the restorer protein revealed that it is part of a soluble mitochondrial inner-membrane-associated, RNase-sensitive high-molecular-weight protein complex. The complex is associated with mRNA derived from the CMS locus.

RFLP analysis for mitochondrial genome of CMS-rice

Restriction fragment length polymorphism (RFLP) was used to analyze mitochondrial (mt) genome of cytoplasmic male sterility (CMS) rice. Differences were observed among mitochondrial genomes of the sterile line (A) and maintain line (B) of nine types of CMS rice; Mitochondrial genomic differences were also detected between A and B in many functional gene regions. Even the materials with the same nucleic background have differences in their mtDNA. This provides molecular evidence for the cytoplasmic heterogeneity and the CMS mechanism research.

Cloning and characterization of the tomato karyopherin alpha1 gene promoter

The karyopherin alpha1 (LeKAPalpha 1) gene of tomato (Lycopersicon esculentum) encodes a receptor involved in nuclear import. To analyze the expression pattern of this gene, a genomic clone containing its upstream region was isolated and sequenced. To study the promoter functionality, a 2170 bp fragment (LM1), was fused to glucuronidase (GUS) and introduced into petunia cells by particle bombardment. For further characterization of the promoter, one inverse and three deletion constructs were studied in cell suspension. To follow its expression in tobacco leaves, transgenic plants expressing GUS under the control of the LM1 promoter were made. Expression of LM1-GUS was largely restricted to actively growing leaf regions, suggesting possible involvement of active cell division and plant growth regulators in LeKAPalpha 1 expression.

Genetic transformation of HeLa cells by Agrobacterium

Agrobacterium tumefaciens is a soil phytopathogen that elicits neoplastic growths on the host plant species. In nature, however, Agrobacterium also may encounter organisms belonging to other kingdoms such as insects and animals that feed on the infected plants. Can Agrobacterium, then, also infect animal cells? Here, we report that Agrobacterium attaches to and genetically transforms several types of human cells. In stably transformed HeLa cells, the integration event occurred at the right border of the tumor-inducing plasmid's transferred-DNA (T-DNA), suggesting bona fide T-DNA transfer and lending support to the notion that Agrobacterium transforms human cells by a mechanism similar to that which it uses for transformation of plants cells. Collectively, our results suggest that Agrobacterium can transport its T-DNA to human cells and integrate it into their genome.

Involvement of two different urf-s related mitochondrial sequences in the molecular evolution of the CMS-specific S-Pcf locus in petunia

In petunia, a mitochondrial (mt) locus, S-Pcf, has been found to be strongly associated with cytoplasmic male sterility (CMS). The S-Pcf locus consists of three open reading frames (ORF) that are co-transcribed. The first ORF, Pcf, contains parts of the atp9 and coxII genes and an unidentified reading frame, urf-s. The second and third ORFs contain NADH dehydrogenase subunit 3 (nad3) and ribosomal protein S12 (rps12) sequences, respectively. The nad3 and rps12 sequences included in the S-Pcf locus are identical to the corresponding sequences on the mt genome of fertile petunia. In both CMS and fertile petunia, only a single copy of nad3 and rps12 had been detected on the physical map of the main mt genome. The origin of the urf-s sequence and the molecular events leading to the formation of the chimeric S-Pcf locus are not known. This paper presents evidence indicating that two different mt sequences, related to urf-s and found in fertile petunia lines (orf-h and Rf-1), might have been involved in the molecular evolution of the S-Pcf locus. Southern analysis of mtDNA derived from both fertile and sterile petunia plants suggests that one of these urf-s related sequences (showing 100% homology to urf-s and termed orf-h) is located on a sublimon. An additional, low-homology urf-s related sequence (Rf-1) is shown to be located on the main mt genome 5' to the nad3 gene. It is, thus, suggested that the sequence of events leading to the generation of the S-Pcf locus might have involved introduction of the orf-h sequence, via homologous recombination, into the main mt genome 5' to nad3 at the region where the Rf-1 sequence is located.

How do alterations in plant mitochondrial genomes disrupt pollen development?

Cytoplasmic male sterility arises when mitochondrial activities are disrupted that are essential for pollen development. Rearrangements in the mitochondrial genome that create novel open reading frames are strongly correlated with CMS phenotypes in a number of systems. The morphological aberrations which indicate CMS-associated degeneration are frequently restricted to the male sporogenous tissue and a limited number of vegetative tissues. In several cases, this tissue specificity may result from interactions between the mitochondrial genome and nuclear genes that regulate mitochondrial gene expression. A molecular mechanism by which CMS might be caused has not been conclusively demonstrated for any system. Several hypotheses for general mechanisms by which mitochondrial dysfunction might disrupt pollen development are discussed, based on similarities between the novel CMS-associated genes from a number of systems.

Molecular aspects of cytoplasmic male sterility in perennial ryegrass (Lolium perenne L.): mtDNA and RNA differences between plants with male-sterile and fertile cytoplasm and restriction mapping of their atp6 and coxI homologous regions

Lolium perenne L. male-sterile and fertile cytoplasms contain different mitochondrial genomes, as revealed by Southern hybridization with a number of heterologous mitochondrial probes. In addition, transcriptional patterns of atp6 and coxI genes distinguish both cytoplasmic types. The majority of the L. perenne sequences from male-sterile and fertile cytoplasm showing homology with these two genes has been cloned and mapped by restriction digestion. A complex genomic organization, especially concerning coxI homologous sequences, was found in the male-sterile cytoplasm. Furthermore, during the course of these studies tissue-culture-induced mtDNA mutations in a number of coxI-containing sequences were detected in regenerated plants.

Cytoplasmic male sterility in sunflower is correlated with the co-transcription of a new open reading frame with the atpA gene

The organization and expression of the mitochondrial (mt) genome of fertile, male-sterile and restored lines of Helianthus annuus and of H. petiolaris were compared to identify alterations which might lead to cytoplasmic male sterility (CMS). The mtDNAs of fertile and male-sterile lines differ by an 11 kb inversion and a 5 kb insertion. The rearrangements seem to be the result of recombination events within an inverted repeat of 261 bp. Detectable alterations in the transcript pattern of the rearranged mtDNA regions are restricted to the atpA locus. The male-sterile line CMSBaso shows three additional transcripts of the atpA locus of about 2500, 1200 and 250 nucleotides which are not detectable in Baso. However, the coding sequences of the atpA gene are entirely identical in the fertile line Baso and the male-sterile line CMSBaso. But a new open reading frame (orfH522) of 522 nucleotides is co-transcribed with the atpA gene as an additional larger transcript of about 2500 nucleotides in CMSBaso. orfH522 is also included in a second additional transcript of about 1200 nucleotides. The predicted translation product of orfH522 might play a role in CMS in sunflower.

Synthesis of male sterile, triazine-resistant Brassica napus by somatic hybridization between cytoplasmic male sterile B. oleracea and atrazine-resistant B. campestris

Fusion of leaf protoplasts from an inbred line of Brassica oleracea ssp. botrytis (cauliflower, n=9) carrying the Ogura (R1) male sterile cytoplasm with hypocotyl protoplasts of B. campestris ssp. oleifera (cv "Candle", n=10) carrying an atrazine-resistant (ATR) cytoplasm resulted in the production of synthetic B. napus (n=19). Thirty-four somatic hybrids were produced; they were characterized for morphology, phosphoglucose isomerase isoenzymes, ribosomal DNA hybridization patterns, chromosome numbers, and organelle composition. All somatic hybrids carried atrazine-resistant chloroplasts derived from B. campestris. The mitochondrial genomes in 19 hybrids were examined by restriction endonuclease and Southern blot analyses. Twelve of the 19 hybrids contained mitochondria showing novel DNA restriction patterns; of these 12 hybrids, 5 were male sterile and 7 were male fertile. The remaining hybrids contained mitochondrial DNA that was identical to that of the ATR parent and all were male fertile.

A new cytoplasmic male sterile genotype in the sugar beet Beta vulgaris L.: a molecular analysis

Mitochondrial DNA (mtDNA) from fertile (N) and possibly new cytoplasmic male sterile (CMS) genotypes was studied in the sugar beet Beta vulgaris L. It was found by restriction endonuclease analysis that BMC-CMS, a cytoplasm that was derived from the wild beet Beta maritima, contained a unique type of mtDNA which is distinguishable from both the N and S-CMS, the only other CMS genotype that is currently availabe in B. vulgaris L. The organization of three genes: coxI, coxII and cob, was analyzed by hybridization with heterologous probes from maize. These genes have a similar structure in N and BMC-CMS that is different from S-CMS. It is concluded that BMC-CMS is a novel CMS genotype in the sugar beet.

Attempts to detect extra genomial factors in cytoplasmic male-sterile petunia lines

In the present study we examined the possibility that viruses, viroids or dsRNA are associated with cytoplasmic male sterile (cms) petunia. The assumption was made that if viruses or viroids were present, the treatments for elimination of viruses and viroids would produce "healthy" fertile plants. Male sterile plants were subjected to heat and cold treatments for 10 weeks and/ or for 5 months, after which apical meristems were isolated and cultured with the addition of antiviral factors. The mother plants, the regenerated plants and their progeny were sterile. These treatments did not affect sterility in sterile plants or the fertility of fertile plants. No dsRNA was found in cms petunia by gel electrophoresis. Thus, our data suggest that there are no viruses, viroids or dsRNA associated with cms petunia. Our data are in agreement with recent data, which suggests that the mitochondrial DNA is the site of the cytoplasmic male sterile gene in petunia.

A fused mitochondrial gene associated with cytoplasmic male sterility is developmentally regulated

Sequencing of an open reading frame associated with cytoplasmic male sterility (CMS) in Petunia has revealed a gene fusion (the Pcf gene) containing the 5'-flanking and amino-terminal transmembrane segment of the ATP synthase proteolipid gene (atp9), parts of the cytochrome oxidase subunit II (coxII) coding region, and the carboxyl terminus and 3'-flanking region of an unidentified reading frame (urfS). The coxII region has several small deletions and tandem repeats that remove all of the segments coding for the residues involved in copper binding, but may possibly maintain the cytochrome c binding site. Normal atp9 and coxII genes and their transcripts are also present in the sterile cytoplasm. S1 nuclease protection studies identify fused gene transcripts only in CMS lines, with an increase in transcript amount in anthers relative to leaves.

Restoration of male fertileNicotiana by fusion of protoplasts derived from two different cytoplasmic male-sterile cybrids

Using the 'donor-recipient' protoplast-fusion technique, we have recently constructed several alloplasmic-like lines ofNicotiana in which the original cytoplasms (or part of them) of eitherN. tabacum orN. sylvestris were replaced respectively, either byN. undulata or byN. bigelovii cytoplasms. These cybridizations resulted in two kinds of cytoplasmic male-sterile (CMS) cybrid plants:N. tabacum withN. undulata-like cytoplasm andN. sylvestris withN. bigelovii-like cytoplasm. Fusion of protoplasts, derived from the above two CMS types, by the 'donor-recipient' technique, lead to the recovery of 21 cybrid calli. One of these regenerated a cybrid with fertile pollen but having shortened filaments and slighly tappered anthers. Self pollination of the latter cybrid resulted in a second generation progeny having almost normal filaments and anthers. Further selfings produced a third generation in which numerous plants had normal stamens and fertile pollen. Mitochondrial DNA (mtDNA) analysis of second and third generation progenies revealed a novel pattern which differed from each of the parental CMS cybrids and also from the mtDNA of normal, male-fertileNicotiana species. The results suggest that mtDNA recombination between different types of CMS can lead to restoration of male-fertility.

Differential fate of plastid and mitochondrial genomes in Petunia somatic hybrids

The chloroplast (cp) and mitochondrial (mt) DNAs of Petunia somatic hybrid plants, which were derived from the fusion of wild-type P. parodii protoplasts with albino P. inflata protoplasts, were analyzed by endonuclease restriction and Southern blot hybridization. Using (32)P-labelled probes that distinguished the two parental cpDNAs at a BamH1 site and at a HpaII site, only the P. parodii chloroplast genome was detected in the 10 somatic hybrid plants analyzed. To examine whether cytoplasmic mixing had resulted in rearrangement of the mitochondrial genome in the somatic hybrids, restriction patterns of purified somatic hybrid and parental mtDNAs were analyzed. Approximately 87% of those restriction fragments which distinguish the two parental genomes are P. inflata-specific. Restriction patterns of the somatic hybrid mtDNAs differ both from the parental patterns and from each other, suggesting that an interaction occurred between the parental mitochondrial genomes in the somatic fusion products which resulted in generation of the novel mtDNA patterns. Southern blot hybridization substantiates this conclusion. In addition, somatic hybrid lines derived from the same fusion product were observed to differ in mtDNA restriction pattern, reflecting a differential sorting-out of mitochondrial genomes at the time the plants were regenerated.