Bohuš Obert

Colchicine, an efficient genome-doubling agent for maize (Zea mays L.) microspores cultured in anthero

Abstract The construction of maize genotypes with high haploid induction capacity made it possible to study the effect of colchicine on maize androgenesis in vitro. Anther cultures of three hybrids were treated with 0.02% and 0.03% colchicine for 3 days at the beginning of microspore induction. Colchicine added to the induction medium had no negative influence on the androgenic responses (anther induction, induction of structures of microspore origin and their regeneration ability) of the genotypes examined. However, significantly higher fertility was observed in plants originating from colchicine-treated microspores, especially at 0.03%. Cytological examinations showed that colchicine treatment before the first microspore division efficiently arrested mitosis and resulted in homozygous doubled-haploid microspores. Under the experimental conditions, the antimitotic drug had no later effect on the division symmetry of the microspore nucleus, and unequal divisions remained dominant. Callus formation from the induced microspores seemed to be more typical (ranging between 60–70%), but embryo frequency was increased by approximately 10%, especially at the higher colchicine concentration. These results suggest that the mechanism of colchicine action in premitotic maize microspores may differ from that previously observed in wheat.

Colchicine induced embryogenesis in maize

The present study involves in vitro androgenesis of Zea mays L. using anther culture. We tested combinations of single factors and their influence on microspore induction. Embryogenic induction of microspores within anthers in in vitro conditions was the best when combination of cold treatment, TIBA (0.1 mg l−1) in media and colchicine (0.02% during first 3 days of culture) was applied, but colchicine alone can be factor, which can stimulate or initiate embryogenesis in anther culture of maize.

Histological study of embryo-like structures initiated from hypocotyl segments of flax (Linum usitatissimum L.).

Cultivation of flax hypocotyl segments on MS medium supplemented with auxin (2,4-d, NAA) and combination of auxin (NAA) and cytokinin (BAP, zeatin) resulted in production of callus on the cut ends of segments and prolonged cultivation in globular structures resembling early stages of somatic embryos. Embryo-like structures protruded on the surface directly from the subepidermal layers of hypocotyl segments. Despite these globular structures closely resembling somatic embryos, histological observations did not reveal their embryogenic character–organogenesis was the predominant developmental morphogenic pathway. Based on our experiments, as well as on critical revision of existing reports on flax somatic embryogenesis, we conclude, that there has not yet been convincing histological proof of somatic embyogenesis from flax hypocotyl segments.

Proteomic and biochemical analysis of maize anthers after cold pretreatment and induction of androgenesis reveals an important role of anti-oxidative enzymes.

In stress conditions, microspores and young pollen grains can be switched from their normal pollen development toward an embryogenic pathway via a process called androgenesis. Androgenic embryos can produce completely homozygous, haploid or double-haploid plants. This study aimed to investigate changes in the abundance of protein species during cold pretreatment and subsequent cultivation of maize anthers on induction media using gel-based proteomics. Proteins upregulated on the third day of anther induction were identified and discussed here. Simultaneous microscopic observations revealed that the first division occurred in microspores within this period. Using 2-D electrophoresis combined with MALDI TOF/TOF MS/MS analysis 19 unique proteins were identified and classified into 8 functional groups. Proteins closely associated with metabolism, protein synthesis and cell structure were the most abundant ones. Importantly, ascorbate peroxidase, an enzyme decomposing hydrogen peroxide, was also upregulated. Isozyme analysis of peroxidases validated the proteomic data and showed increased peroxidase activities during androgenic induction. Further, the isozyme pattern of SOD revealed increased activity of the MnSOD, which could provide hydrogen peroxide as a substrate for in vivo peroxidase reactions (including ascorbate peroxidase). Together, these data reveal the role of enzymes controlling oxidative stress during induction of maize androgenesis.

Flax anther culture: effect of genotype, cold treatment and media

We report on screening of wide range of flax cultivars for androgenic response and on testing of induction conditions for flax (Linum usitatissimum L.) anther culture and plant regeneration. Anthers were cultured on four different media: Mo, N6, MS and N&N supplemented with various combinations of growth regulators. The induction of callus formation from cultured anthers was the highest on N6 (with cultivar PR FGL 77 – 12 %) and N&N media (with cultivar Carolin – 2.8 %), preferentially after cold pretreatment (7days at 8 °C). Shoots were formed on calli derived from the microspores inside the cultured anthers on media N&N and N6 supplemented with 1 mg l−1 zeatin or 1 mg l−1BAP + 1 mg l−1NAA, respectively and elongated on MS medium supplemented with 2 mg l−1 zeatin. The highest number of shoots (120) was observed with cultivar Red Wing. Shoots were rooted on MS medium supplemented with 2 mg l−1IAA. Our experiments resulted in total in 62 % anther response and 155 plants regenerated and transferred into soil.

Haploid formation in maize, barley, flax, and potato

Summary.The article is reviewing some significant features and issues in the process of haploid formation in two important monocotyledonous crop plants – maize and barley – and in two dicotyledonous plants – flax and potato. Exotic maize lines with higher androgenic response turned up as a good source for this heritable trait and this valuable trait can be incorporated into elite maize lines via crossing. Lots of attempts were devoted to identifying some cytological and/or morphological markers for androgenic response in maize microspore cultures. The “starlike” organization of the cytoplasm inside the induced maize microspores together with the enlarged size of induced microspores can be considered as morphological markers for androgenic response. In barley, microspores with rich cytoplasm that was of granular appearance with the nucleus located near the cell wall and with no visible vacuole had the largest survival rate and many of these cells continued in development and produced embryos. In flax, a dramatic increase of induction rate in anther cultures (up to 25%) was achieved when flax anthers were pretreated for 3 days at 4 °C and afterwards kept for 1 day at 35 °C. Also gynogenesis in flax has been reported already and complete plants were obtained. In potato microspore cultures, formation of two dissimilar cells indicated a strong polarization in the system and as a result of this polarization a prominent suspensor developed that persisted until the torpedo stage of the androgenic embryo. This was the first time the formation of a well developed suspensor was described in connection with androgenesis.

Comparative quantitative proteomic analysis of embryogenic and non-embryogenic calli in maize suggests the role of oxylipins in plant totipotency.

UNLABELLED Totipotency, the ability of somatic plant cell to generate whole plant through somatic embryogenesis, is still not well understood. In this study, maize immature zygotic embryos were used to generate embryogenic (EC) and non-embryogenic (NEC) calli. In order to compare proteomes of EC and NEC, two-dimensional electrophoresis (2-DE) in combination with mass spectrometry was used. This approach resulted into 361 quantified 2-DE spots out of which 44 were found statistically significantly differentially abundant between EC and NEC. Mass spectrometry provided the identity for 23 proteins that were classified into 8 metabolic categories. The most abundant were proteins associated with energy followed by proteins associated with disease and defense. Based on the abundances of identified proteins in this and other studies, working model for plant totipotency was proposed. One aspect of this working model suggests that increased abundances of proteins associated with pyruvate biosynthesis and suppression of embryogenic genes might be responsible for differences between EC and NEC cells. Furthermore we speculate that the increased abundance of lipoxygenase in the NEC cells results in changes in the equilibrium levels of one or more signaling molecules and is at least partly responsible for somatic cell reprogramming during totipotency. BIOLOGICAL SIGNIFICANCE Totipotency, the ability of somatic plant cell to generate whole plant through somatic embryogenesis, is still not well understood. In order to further advance understanding of this biological phenomenon, proteomes of embryogenic and non-embryogenic callus, derived from immature zygotic embryos of inbred maize line A19, were compared using 2-DE based proteomic technology. Based on the abundances of identified proteins in this and other studies, working model for plant totipotency was proposed. One aspect of this working model suggests that increased abundances of proteins associated with pyruvate biosynthesis and suppression of embryogenic genes might be responsible for differences between EC and NEC cells. Furthermore we speculate that the increased abundance of lipoxygenase in the NEC cells results in changes in the equilibrium levels of one or more signaling molecules and is at least partly responsible for somatic cell reprogramming during totipotency. This article is part of a Special Issue entitled: Environmental and structural proteomics.

Doubled haploid production in Flax (Linum usitatissimum L.).

There is a requirement of haploid and double haploid material and homozygous lines for cell culture studies and breeding in flax. Anther culture is currently the most successful method producing doubled haploid lines in flax. Recently, ovary culture was also described as a good source of doubled haploids. In this review we focus on tissue and plants regeneration using anther culture, and cultivation of ovaries containing unfertilized ovules. The effect of genotype, physiological status of donor plants, donor material pre-treatment and cultivation conditions for flax anthers and ovaries is discussed here. The process of plant regeneration from anther and ovary derived calli is also in the focus of this review. Attention is paid to the ploidy level of regenerated tissue and to the use of molecular markers for determining of gametic origin of flax plants derived from anther and ovary cultures. Finally, some future prospects on the use of doubled haploids in flax biotechnology are outlined here.

Dihaploid Production in Flax by Anther and Ovary Cultures

Abstract The response of flax anther cultures is still very genotype dependent. We screened different flax genotypes (Szegedi 30, Flanders, Carolin, PR FGL 77, Viking and Red Wing) for androgenic response. The highest androgenic response for each genotype was achieved on N&N medium supplemented with 6% sucrose and combination of growth hormones (1 mg l−1 NAA and 1 mg l−1 BAP) after the anthers were cold pretreated at 8°C for 7 days. The highest number of calli and shoots were derived with genotype Red Wing. In case of Red Wing even embryo-like structures were regenerated from the calli. For gynogenesis this is the first report on ovary cultures in flax. The obtained response (number of ovaries producing calli) ranged from 4% in genotype PR FGL 62 to 64% in genotype AC Emerson on N6 medium supplemented with the same sucrose and hormone combination and concentration as for anther cultures. Yellow calli were formed within two to four months and in course of cultivation turned green. Regeneration was realized via shoot formation. Cells in the yellow calli were preferentially diploid (2n) and in green ones tetraploid (4n) and also higher ploidy level was observed (up to 16n) in course of cultivation.

Total protein and isozyme characterization in the flax zygotic embryo during development

Abstract  Flax zygotic embryogenesis was studied for isozyme patterns of acid phosphatase and esterase and for content of total proteins. For acid phosphatase, six multiple molecular forms or isozymes, were identified during flax zygotic embryo development. For esterase, six isozymes were expressed during zygotic flax embryogenesis. Some of the isozymes were expressed during entire embryogenesis, and some were only transiently expressed or appeared near maturation. The amount of total proteins was very low at early embryogenesis and proteins in a range from 26.6 kDa to 97.4 kDa were expressed. During further flax embryo development the protein spectra became more diverse and the quantity of total proteins increased. Proteins ranging from 3.4 kDa to 97.4 kDa were present, and proteins of 20 kDa to 36.5 kDa were expressed in the highest amount. The results are discussed with reference to selected information in the literature.