Root cryopreservation to biobank medicinal plants: a case study for Hypericum perforatum L.

In this study, an effective root-based cryopreservation method was developed for Hypericum perforatum L., an important medicinal species, using in vitro plants. A systematic approach was applied to determine effective combinations of protocol steps such as preculture, osmoprotection, vitrification solution treatment, and unloading, followed by protocol optimization using a single-factor approach. The effects of root section type (root tips, middle sections, or basal sections), duration of root section culture after excision, and donor plant age were also investigated. In a wild genotype, middle and basal root sections excised from 8-wk-old plants and cryopreserved at the age of 10 d after excision showed the highest plant regrowth after cryopreservation. In the optimized protocol, root sections were precultured in 10% (w/v) sucrose for 17 h, osmoprotected with a solution composed of 17.5% (w/v) glycerol and 17.5% (w/v) sucrose for 20 min, followed by a vitrification solution of 40% (w/v) glycerol and 40% (w/v) sucrose for 30 min, and cryopreserved using aluminum foil strips (droplet-vitrification). After rewarming in preheated 25% (w/v) sucrose solution and 30-min unloading, root segments were recovered on medium supplemented with 1.0 mg L⁻¹ gibberellic acid and showed 78% plant regrowth. This cryopreservation method was successfully adapted for five elite lines of H. perforatum with a 45 to 87% regrowth rate after cryopreservation. These results suggest that root cryopreservation may be an effective method for medicinal plant conservation and should be tested with a broader range of species.

     

Growth and development temperature influences level of tolerance to high light stress

The influence of growth and development temperature on the relative tolerance of photosynthetic tissue to high light stress at chilling temperatures was investigated. Two tuber-bearing potato species, Solanum tuberosum L. cv Red Pontiac and Solanum commersonii were grown for 4 weeks, at either 12 or 24°C with 12 hours of about 375 micromoles per second per square meter of photosynthetically active radiation. Paired leaf discs were cut from directly across the midvein of leaflets of comparable developmental stage and light environment from each species at each growth temperature treatment. One disc of each pair was exposed to 1°C and about 1000 micromoles per second per square meter photosynthetically active radiation for 4 hours, and the other disc was held at 1°C in total darkness for the same duration. Photosynthetic tissue of S. tuberosum, developed at 12°C, was much more tolerant to high light and low temperature stress than tissue developed under 24°C conditions. Following the high light treatment, 24°C-grown S. tuberosum tissue demonstrated light-limited and light-saturated rates that were approximately 50% of their paired dark controls. In contrast, the 12°C-grown tissue from S. tuberosum that was subjected to the light stress showed only a 18 and 6% reduction in light-limited and light-saturated rates of photosynthetic oxygen evolution, respectively. Tissue from 24°C-grown S. commersonii was much less sensitive to the light stress than was tissue from S. tuberosum grown under the same conditions. The results presented here demonstrate that: (a) acclimation of S. tuberosum to lower temperature growth conditions with a constant light environment, results in the increased capacity of photosynthetic tissue to tolerate high light stress at chilling temperature and (b) following growth and development at relatively high temperatures S. commersonii, a frost- and heat-tolerant wild species, has a much greater tolerance to the high light stress at chilling temperature than does S. tuberosum cv Red Pontiac, a frost-sensitive cultivated species.     

Characterisation of somatic hybrids between Solanum tuberosum and its frost-tolerant relative Solanum commersonil

 Somatic hybrids between three dihaploid Solanum tuberosum (2n=2x=24) genotypes and the frost-tolerant, diploid, relative Solanum commersonii (2n=2x=24) were analysed for variation in morphological traits, fertility and frost tolerance. The somatic hybrids were more vigorous than their parents and in many ways resembled a tetraploid S. tuberosum. All of the hybrids flowered profusely, although the male fertility was largely dependent on the S. tuberosum genotype used. In one hybrid combination all plants were both male- and female-fertile, while in the other two combinations the majority of plants were male-sterile but female-fertile. The somatic hybrids showed an increase in direct frost tolerance when compared with the dihaploid S. tuberosum parents, and to a varying extent had gained the capacity to cold acclimate. These somatic hybrids will be used in breeding programmes involving repeated cycles of anther culture and somatic hybridisation. Received: 20 May 1997 / Accepted: 12 June 1997     

Fertile Solanum tuberosum+S. commersonii somatic hybrids as sources of resistance to bacterial wilt caused by Ralstonia solanacearum

 The wild potato relative Solanum commersonii is reported to carry resistance to bacterial wilt disease caused by Ralstonia solanacearum. To overcome sexual incompatibilites due to differences in ploidy and endosperm balance numbers, somatic hybrids were made that combine the S. tuberosum and S. commersonii genomes. The resulting somatic hybrid plants are vigorous, but their disease resistance level and their fertility was unknown. We therefore tested the S. commersonii and S. tuberosum source material cv Superior, potato cv Atlantic and six somatic hybrid lines for resistance to a virulent strain of R. solanacearum (race 3, biovar 2) at 28°C. As expected, S. commersonii was significantly more wilt-resistant than the cultivated potatoes. In five of the six somatic hybrid lines, disease resistance levels were similar to that of the resistant S. commersonii parent. The resistance level of the sixth somatic hybrid was intermediate, significantly different from both S. commersonii and S. tuberosum. In controlled crosses, the somatic hybrids in this study proved both to be male- and female-fertile and were self-compatible. More importantly, the somatic hybrids can be crossed with S. tuberosum to produce viable seeds. Received: 23 June 1998 / Accepted: 13 October 1998     

Cloning and Functional Characterization of SAD Genes in Potato

Stearoyl-acyl carrier protein desaturase (SAD), locating in the plastid stroma, is an important fatty acid biosynthetic enzyme in higher plants. SAD catalyzes desaturation of stearoyl-ACP to oleyl-ACP and plays a key role in determining the homeostasis between saturated fatty acids and unsaturated fatty acids, which is an important player in cold acclimation in plants. Here, four new full-length cDNA of SADs (ScoSAD, SaSAD, ScaSAD and StSAD) were cloned from four Solanum species, Solanum commersonii, S. acaule, S. cardiophyllum and S. tuberosum, respectively. The ORF of the four SADs were 1182 bp in length, encoding 393 amino acids. A sequence alignment indicated 13 amino acids varied among the SADs of three wild species. Further analysis showed that the freezing tolerance and cold acclimation capacity of S. commersonii are similar to S. acaule and their SAD amino acid sequences were identical but differed from that of S. cardiophyllum, which is sensitive to freezing. Furthermore, the sequence alignments between StSAD and ScoSAD indicated that only 7 different amino acids at residues were found in SAD of S. tuberosum (Zhongshu8) against the protein sequence of ScoSAD. A phylogenetic analysis showed the three wild potato species had the closest genetic relationship with the SAD of S. lycopersicum and Nicotiana tomentosiformis but not S. tuberosum. The SAD gene from S. commersonii (ScoSAD) was cloned into multiple sites of the pBI121 plant binary vector and transformed into the cultivated potato variety Zhongshu 8. A freeze tolerance analysis showed overexpression of the ScoSAD gene in transgenic plants significantly enhanced freeze tolerance in cv. Zhongshu 8 and increased their linoleic acid content, suggesting that linoleic acid likely plays a key role in improving freeze tolerance in potato plants. This study provided some new insights into how SAD regulates in the freezing tolerance and cold acclimation in potato.     

Analysis of late-blight disease resistance and freezing tolerance in transgenic potato plants expressing sense and antisense genes for an osmotin-like protein

The expression patterns of plant defense genes encoding osmotin and osmotin-like proteins imply a dual function in osmotic stress and plant pathogen defense. We have produced transgenic potato (Solanum commersonii Dun.) plants constitutively expressing sense or antisense RNAs from chimeric gene constructs consisting of the cauliflower mosaic virus 35S promoter and a cDNA (pA13) for an osmotin-like protein. Transgenic potato plants expressing high levels of the pA13 osmotin-like protein showed an increased tolerance to the late-blight fungus Phytophthora infestans at various phases of infection, with a greater resistance at an early phase of fungal infection. There was a decrease in the accumulation of osmotin-like mRNAs and proteins when antisense transformants were challenged by fungal infection, although the antisense transformants did not exhibit any alterations in disease susceptibility. Expression of pA13 sense and antisense RNAs had no effect on the development of freezing tolerance in transgenic plants when assayed under a variety of conditions including treatments with abscisic acid or low temperature. These results provide evidence of antifungal activity for a potato osmotin-like protein against the fungus P. infestans, but do not indicate that pA13 osmotin-like protein is a major determinant of freezing tolerance.     

Development of a common PVS2 vitrification method for cryopreservation of several fruit and vegetable crops

Many cryopreservation techniques are currently available, and it is common for new modifications to be developed for individual crops or specific genotypes. In this study, results of variations of the PVS2 cryopreservation protocol are compared to provide evidence for the suitability of a standard form of this technique for cryopreservation of a range of fruit, berry crops, and potato. Shoot cultures of Malus, Solanum, Lonicera, and Berberis were tested with variations of cold acclimation, pretreatment media, and PVS2 exposure times. A general protocol with some modifications was produced that was suitable for all four genera. The regenerative capacity of shoot tips after cryopreservation by this method exceeded a mean of 50% for Malus, Solanum, Lonicera, and Berberis, which is sufficient for setting storage in a cryobank. After liquid nitrogen storage, the shoot cultures that survived had a healthy appearance and developed rapidly. For each species tested, the only optimization required was the preparation of donor plants by cold acclimation and pretreatment. The choice of one common method simplifies the methodology for conducting experiments and storing a range of germplasm. The use of the PVS2 vitrification method with a 0.3-M sucrose pretreatment is multiuse and can be recommended as the most effective method for the cryopreservation of shoot tips from many plant species.     

Freezing tolerance, cold acclimation and oxidative stress in potato. Paraquat tolerance is related to acclimation but is a poor indicator of freezing tolerance

Potato is a species commonly cultivated in temperate areas where the growing season may be interrupted by frosts, resulting in loss of yield. Cultivated potato, Solanum tuberosum, is freezing sensitive, but it has several freezing-tolerant wild potato relatives, one of which is S. commersonii. Our study was aimed to resolve the relationship between enhanced freezing tolerance, acclimation capacity and capacity to tolerate active oxygen species. To be able to characterize freezing tolerant ideotypes, a potato population (S1), which segregates in freezing tolerance, acclimation capacity and capacity to tolerate superoxide radicals, was produced by selfing a somatic hybrid between a freezing-tolerant Solanum commersonii (LT₅₀=-4.6°C) and -sensitive S. tuberosum (LT₅₀=-3.0°C). The distribution of non-acclimated freezing tolerance (NA-freezing tolerance) of the S1 population varied between the parental lines and we were able to identify genotypes, having significantly high or low NA-freezing tolerance. When a population of 25 genotypes was tested both for NA-freezing and paraquat (PQ) tolerance, no correlation was found between these two traits (R = 0.02). However, the most NA-freezing tolerant genotypes were also among the most PQ tolerant plants. Simultaneously, one of the NA-freezing sensitive genotypes (2022) (LT₅₀=-3.0°C) was observed to be PQ tolerant. These conflicting results may reflect a significant, but not obligatory, role of superoxide scavenging mechanisms in the NA-freezing tolerance of S. commersonii. The freezing tolerance after cold acclimation (CA-freezing tolerance) and the acclimation capacity (AC) was measured after acclimation for 7 days at 4/2°C. Lack of correlation between NA-freezing tolerance and AC (R =-0.05) in the S1 population points to independent genetic control of NA-freezing tolerance and AC in Solanum sp. Increased freezing tolerance after cold acclimation was clearly related to PQ tolerance of all S1 genotypes, especially those having good acclimation capacity. The rapid loss of improved PQ tolerance under deacclimation conditions confirmed the close relationship between the process of cold acclimation and enhanced PQ tolerance. Here, we report an increased PQ tolerance in cold-acclimated plants compared to non-acclimated controls. However, we concluded that high PQ tolerance is not a good indicator of actual freezing tolerance and should not be used as a selectable marker for the identification of a freezing-tolerant genotype.     

Survival and genetic stability of Picea abies embryogenic cultures after cryopreservation using a pregrowth-dehydration method

A vitrification method enabled efficient cryopreservation of embryogenic tissue (ETs) of Norway spruce (Picea abies L.) at ?196 °C in liquid nitrogen (LN). Correctly formed, normal somatic embryos were generated from ETs that had been thawed after removal from LN. The pregrowth-dehydration method involved preculture of ETs with sucrose (0.25–1.00 M) in the presence or absence of 10 μM abscisic acid (ABA), followed by air-drying for 2 h and rapid freezing in LN. Pretreatment of ETs with both sucrose and ABA promoted ET growth after preculture and thawing more effectively than treatment with sucrose alone. Survival of ETs after thawing from LN using both sucrose and ABA was 54.4 % compared to pretreatment with sucrose alone which was 20 %. Addition of ABA in the preculture medium also improved the ability of ETs to form cotyledonary stage somatic embryos. The somatic embryos, which had normal shoot and root apices and the correct number of cotyledons, were indistinguishable from regenerants obtained from control cultures. Genetic analysis of control and cryopreserved ETs, as well as somatic embryos derived from cryopreserved ETs, indicated that the cryopreservation method had no effect on any of the five microsatellite loci (SpAGC1, SpAGC2, SpAGG3, SpAC1H8, and SpAC1F7) tested. The cryopreservation protocol outlined should enable the long-term storage of valuable clones of Norway spruce in LN, potentially for hundreds of years.     

Complete chloroplast genome sequences of <Emphasis Type="Italic">Solanum commersonii</Emphasis> and its application to chloroplast genotype in somatic hybrids with <Emphasis Type="Italic">Solanum tuberosum</Emphasis>

Key message

Chloroplast genome of Solanum commersonii and S olanum tuberosum were completely sequenced, and Indel markers were successfully applied to distinguish chlorotypes demonstrating the chloroplast genome was randomly distributed during protoplast fusion.

Abstract

Somatic hybridization has been widely employed for the introgression of resistance to several diseases from wild Solanum species to overcome sexual barriers in potato breeding. Solanum commersonii is a major resource used as a parent line in somatic hybridization to improve bacterial wilt resistance in interspecies transfer to cultivated potato (S. tuberosum). Here, we sequenced the complete chloroplast genomes of Lz3.2 (S. commersonii) and S. tuberosum (PT56), which were used to develop fusion products, then compared them with those of five members of the Solanaceae family, S. tuberosum, Capsicum annum, S. lycopersicum, S. bulbocastanum and S. nigrum and Coffea arabica as an out-group. We then developed Indel markers for application in chloroplast genotyping. The complete chloroplast genome of Lz3.2 is composed of 155,525 bp, which is larger than the PT56 genome with 155,296 bp. Gene content, order and orientation of the S. commersonii chloroplast genome were highly conserved with those of other Solanaceae species, and the phylogenetic tree revealed that S. commersonii is located within the same node of S. tuberosum. However, sequence alignment revealed nine Indels between S. commersonii and S. tuberosum in their chloroplast genomes, allowing two Indel markers to be developed. The markers could distinguish the two species and were successfully applied to chloroplast genotyping (chlorotype) in somatic hybrids and their progenies. The results obtained in this study confirmed the random distribution of the chloroplast genome during protoplast fusion and its maternal inheritance and can be applied to select proper plastid genotypes in potato breeding program.

     

The Solanum commersonii Genome Sequence Provides Insights into Adaptation to Stress Conditions and Genome Evolution of Wild Potato Relatives

Here, we report the draft genome sequence of Solanum commersonii, which consists of ∼830 megabases with an N50 of 44,303 bp anchored to 12 chromosomes, using the potato (Solanum tuberosum) genome sequence as a reference. Compared with potato, S. commersonii shows a striking reduction in heterozygosity (1.5% versus 53 to 59%), and differences in genome sizes were mainly due to variations in intergenic sequence length. Gene annotation by ab initio prediction supported by RNA-seq data produced a catalog of 1703 predicted microRNAs, 18,882 long noncoding RNAs of which 20% are shown to target cold-responsive genes, and 39,290 protein-coding genes with a significant repertoire of nonredundant nucleotide binding site-encoding genes and 126 cold-related genes that are lacking in S. tuberosum. Phylogenetic analyses indicate that domesticated potato and S. commersonii lineages diverged ∼2.3 million years ago. Three duplication periods corresponding to genome enrichment for particular gene families related to response to salt stress, water transport, growth, and defense response were discovered. The draft genome sequence of S. commersonii substantially increases our understanding of the domesticated germplasm, facilitating translation of acquired knowledge into advances in crop stability in light of global climate and environmental changes.     

Temperature response of plasma membranes in tuber-bearing solanum species

Permeability coefficients (Kp) of nonelectroytes were determined at several temperatures for nonacclimated and acclimated plasma membranes of the frost sensitive Solanum tuberosum and the frost resistant Solanum commersonii. In nonacclimated membranes, Kp were equal at 25°C for the two species. Kp decreased with decreased temperature in both species; however, the decrease was much greater in the frost sensitive S. tuberosum than in frost resistant S. commersonii.

Kp increased with cold acclimation. After acclimation the temperature sensitivity of Kp or activation energy (Ea) for S. tuberosum was similar to that of S. commersonii; however, Kp for S. tuberosum were lower than those for S. commersonii at all temperatures.

The differences in Kp and activation energy indicate plasma membrane differences between the species before acclimation. After acclimation there was still a difference between the plasma membranes of the two species as well as a difference between the nonacclimated and acclimated membranes of the same species.

     

Physiological changes in gentian axillary buds during two-step preculturing with sucrose that conferred high levels of tolerance to desiccation and cryopreservation

BACKGROUND AND AIMS: Induction of dehydration tolerance is a key to achieving high survival rates in cryopreservation of plant specimens. It has been reported previously that two-step preculturing with sucrose effectively increased desiccation tolerance in axillary buds of gentian (Gentiana scabra), which allow the buds to survive cryopreservation. This study is aimed at characterizing each step of this preculturing and to elucidate physiological changes induced during this preculturing. METHODS: In standard two-step preculture, excised gentian axillary buds were incubated for 11 d on MS medium with 0.1 m sucrose at 25 degrees C (first step: mild osmotic stress was given) and the subsequent incubation on MS medium with 0.4 m and 0.7 m sucrose for 1 d each (second step). The levels of abscisic acid (ABA), proline and soluble sugars in gentian buds during the preculture were determined. Effects of various combinations of two-step preculturing and of exogenous ABA and proline were studied. KEY RESULTS: During the first preculture step, there was a transient increase in ABA content peaking on day 4, which declined to a background level at the end of the first and second step preculturing. Proline level increased steadily during the first preculture step and increased further in the second preculture step. Incubating buds with medium containing proline, instead of the two-step preculturing, did not allow them to survive desiccation. Incubating buds with ABA instead of 0.1 m sucrose-preculturing effectively increased desiccation tolerance only when it was followed by the second preculture step. Fluridone, an ABA synthesis inhibitor included in the two-step preculture medium, reduced desiccation tolerance of the buds. The normal first-step preculture increased the levels of soluble sugars 2.4-fold, especially sucrose and raffinose. Buds treated with the second preculture step had greatly increased sucrose levels. CONCLUSIONS: These observations lead to the hypothesis that the first preculture step involves ABA-mediated cellular changes and the second step induces loading of sucrose in the gentian buds.     

Cytology of Potato Callus Cells in Relation to their Frost Hardiness

Structure of callus cells of frost-sensitive and frost-tolerant Solanum species and a frost-tolerant cell line (D20-1), selected from S. tuberosum cv. Desirée callus, was studied. Like frost-tolerant species S. commersonii, cells of the frost-tolerant cell line contained starch grains in their plastids. The cells of this frost-tolerant line also possessed an increased number of microbodies containing protein crystals which suggests the involvement of proteins in frost tolerance but the mechanism may differ from that in frost-tolerant species.     

Biochemical Changes in Tuber-bearing Solanum Species in Relation to Frost Hardiness during Cold Acclimation

Biochemical changes in potato leaves during cold acclimation have been examined and compared between a frost-tolerant S. acaule and a frost-susceptible S. tuberosum species. Changes were also examined in S. tuberosum, S. acaule, and S. commersonii species when they were hardened at different temperatures to varying hardiness levels.     

The survival of in vitro shoot tips of Garcinia mangostana L. after cryopreservation by vitrification

This report highlights the first successful cryopreservation protocol for shoot tips of Garcinia mangostana L. achieved by using vitrification technique. We investigated the effects of different temperatures and exposure periods to a plant vitrification solution 2 (PVS2), sucrose concentrations and preculture periods, and unloading treatments in steps of the vitrification protocol on the survival of G. mangostana shoot tips after cryopreservation. Exposure to PVS2 for 25 min gave beneficial effects with 10.4 ± 1.8 % survival at 0 °C with average water content of 1.1 ± 0.3 g g^?1 dry mass. Survival was 13.7 ± 5.5 % when using preculture medium with full-strength Murashige and Skoog (MS) medium supplemented with 0.6 M sucrose for 2 days. A significant difference was observed in survival of shoot tips when treated with various sucrose concentrations in preculture which strengthens their importance towards enhancing survival of shoot tips after cryopreservation. MS with 0.4 M sucrose and 2 M glycerol applied as an unloading solution increased the survival of shoot tips to 44.1 ± 6.5 %. Experiments on the effect of ascorbic acid were also conducted for each step of vitrification. Our results showed higher survival of 45.8 ± 3.8 % but there were no significant effects compared with the control (without ascorbic acid). Further study on the recovery dark/light period was conducted. Survival of shoot tips significantly increased to 50.0 ± 16.7 % when subjected to 7 days in the dark before transferring to 16 h/8 h light/dark photoperiod. These studies strengthen suggestions that cryopreservation through vitrification is possible for ex situ conservation of germplasm of this tropical recalcitrant species.     

Investigating the cryopreservation of nodal explants of Lithodora rosmarinifolia (Ten.) Johnst., a rare, endemic Mediterranean species

In this study, we investigated the possibility of using the droplet-vitrification technique for cryopreserving nodal segments of in vitro plantlets of the endangered plant species Lithodora rosmarinifolia. Among the three vitrification solutions tested, only solutions B1, containing (w/v) 50 % glycerol and 50 % sucrose, and B3, containing 40 % glycerol and 40 % sucrose, were able to induce cryotolerance in nodal explants, resulting in intermediate survival and recovery after cryopreservation. A three-step vitrification protocol, including an additional dehydration treatment with half-strength vitrification solution for 30 min before the treatment with full-strength vitrification solution, did not lead to any improvement in survival and recovery compared with the two-step protocol. The optimal protocol was the following: preculture of nodal segments in liquid medium with 0.3 M sucrose for 16 h and 0.7 M sucrose for 5 h, treatment for 20 min in loading solution containing 1.9 M glycerol + 0.5 M sucrose, dehydration with vitrification solution B1 (glycerol 50.0 %, sucrose 50.0 %, w/v) for 60 min at room temperature, rapid cooling in minute droplets of vitrification solution, and rapid rewarming by immersion of nodal segments for 20 min in unloading solution containing 1.2 M sucrose. Under these conditions, 33 % recovery of cryopreserved nodal explants was achieved. Regrowth of cryopreserved samples was rapid and direct. These results indicate that long-term storage of L. rosmarinifolia by means of cryopreservation of nodal segments is possible, thereby contributing to securing the diversity of this rare and endangered plant species.