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International Camellia Society

Establishment and characterization of a field germplasm bank of Camellia reference cultivars

Vela P.1, Salinero C.1, Sainz M.J.2, González M.1, Couselo J.L.1 , Spain
1 Estación Fitopatolóxica do Areeiro, Deputación de Pontevedra. Subida a la Robleda, s/n. 36153 Pontevedra, Spain. efa@efa-dip.org
2 Departamento de Producción Vegetal, Universidad de Santiago de Compostela. Campus Universitario s/n, 27002 Lugo, Spain.

Introduction

In the gardens around the world grow old specimens of different camellia cultivars, which are part of the cultural heritage of each country and an important reservoir of germplasm. Many of these cultivars were originated in Asia over 400 years ago or in Western countries during the nineteenth century.

The exact date of introduction of camellia plants to Western countries is not known, as the existing documentation on the subject is scarce and confusing. Thousands of camellia cultivars were extensively cultivated in Europe during the nineteenth century but camellia plants were moved from one country to another without any control and often with the wrong name. Many nurseries involved in producing camellia plants from rooted cuttings or seeds gave different names to cultivars whose variations were insignificant and unstable. In addition, some cultivars were designated differently depending on the place they were grown, increasing the confusion that already existed in the nomenclature.

During the first half of the twentieth century, the interest in camellias decreased, with many of them abandoned in the gardens. However, some of these neglected camellias survived until today, losing in most cases their original names and part of their history.

Nowadays the International Camellia Register (ICR) comprises over 32,000 camellia cultivars -mostly belonging to Camellia japonica - a number that is increasing each year with the introduction of new cultivars. The ICR includes all the cultivars for which there is any written reference or description of the flower and in some cases the plant, but without checking if a particular cultivar is already registered under a different name. Moreover, many of the camellia descriptions gathered by the ICR are brief, inaccurate and insufficient. Thus, the actual number of existing cultivars could be lower than those compiled by the ICR.
In order to know the real number of cultivars included within each species, duplicated and wrongly identified cultivars within the ICR should be detected. The key issue could be the establishment of reference camellia cultivars from the characterization of cultivars originated in the nineteenth century and earlier, whose names were lost during the twentieth century. The study of these old cultivars should consider the historical, cultural and botanical background.

First works on the study of old camellias began in the late years of the twentieth century mainly in Belgium, Italy, Portugal and Spain. Some old camellia plants from these countries were characterized by comparing their morphological features with information available at the ICR, in nursery catalogs, in drawings included in nineteenth century publications, and when possible with well-identified plants maintained in living collections. Morphological analysis is the traditional and most used tool for the identification of camellia species and cultivars. It is based on agromorphological traits of the flower and the leaf, bush size, disease resistance, cold hardiness, etc., but these descriptors can be influenced by ontogenic and environmental factors that may alter the size, colour and even the shape of the flower, masking the real genetic diversity (Banerjee, 1992; Trehane, 2007). Furthermore, some morphological features, especially those of flowers, are highly variable among individuals belonging to the same cultivar and even among flowers of the same plant, hindering their visual assessment by researchers. For this reason, the identification of camellia cultivars which relies only on the analysis of morphobotanical characters is insufficient, particularly for those of Camellia japonica

Molecular techniques based on DNA analysis have proven useful for the characterization of plant material in a number of wild and cultivated species (Mohan et al., 1997; Ouborg et al., 1999). In particular, microsatellites were the most useful and reliable molecular markers for cultivar identification in many plants.

Over 50 microsatellite loci in the genomic DNA of Camellia sinensis have been described and successfully used for the study of tea plant material (Kaundun and Matsumoto, 2002, 2004; Freeman et al., 2004; Hung et al., 2008; Zhao et al., 2008). Some of these microsatellites are also present in the genomic DNA of C. japonica, and could be effective for the characterization of cultivars of this species, as an additional tool to the classical identification based on morphological characters.

The aim of the present work was to find and characterize, by using morphological and molecular techniques, old plants of Camellia japonica growing in public and private gardens in Spain and other European countries, as the basis for the establishment of a germplasm bank of C. japonica reference cultivars.

Material and Methods

Camellia plant material was obtained from 31 old individuals from Germany, Italy, Portugal and Spain, and from 18 plants of different cultivars maintained at two locations (Areeiro and Soutomaior) belonging to the Spanish living camellia germplasm collection of Deputación de Pontevedra (Table 1).

A survey to search for old plants with recognizable features of known 19th century camellia cultivars was carried out in Galician (NW Spain) and North Portugal gardens. Seventeen plants (15 in Spain and 2 in Portugal) belonging to different old cultivars were found.

Another old camellia cultivar belonged to the botanical collection of Palmengarten (Frankfurt, Germany). The remaining 13 old individuals were part of Villa Annelli garden collection (Oggebbio, Italy).
Plants belonging to the Spanish living camellia germplasm collection were established from commercial nursery plant material between 1985 and 1989.

Table 1. Camellia japonica cultivars of the field germplasm bank with data on origin, location and first known written reference.

CULTIVAR	Origin	First written reference	LOCATION
Akashigata	Japan	1859	Castillo de Soutomaior	Spain
Alba Plena	China	1797	Pazo de Santa Cruz de Ribadulla	Spain
Anemoniflora (Waratah)	China	1806	Pazo de Santa Cruz de Ribadulla	Spain
Angela Cocchi	Italy	1856	Villa Anelli	Italy
Antonio Bernardo Ferreira	Portugal	1883	Pazo de Santa Cruz de Ribadulla	Spain
Baronne Leguay	France	1873	Castillo de Soutomaior	Spain
Bella Lambertii	Italy	1851	Castillo de Soutomaior	Spain
Bella Portuense	Portugal	1865	E. F. do Areeiro	Spain
Bella Romana	Italy	1856	Pazo de Lourizan	Spain
Compacta Alba	France	1839	Castillo de Soutomaior	Spain
Daikagura (Ortigueira)	Japan	1788	Pazo de Santa Cruz de Ribadulla	Spain
Daviesii	UK	1843	Pazo de Santa Cruz de Ribadulla	Spain
Doutor Balthazar de Mello	Portugal	1891	Pazo de Santa Cruz de Ribadulla	Spain
Eugenia de Montijo	Spain	1897	Castillo de Soutomaior	Spain
Federicci	Italy	1849	Jardim Botanico de Porto	Portugal
Gigantea	UK	1830	Pazo de Torres Agrelo	Spain
Gran Sultan	Italy	1841	Villa Anelli	Italy
Grandiflora Superba	France	1840	Castillo de Soutomaior	Spain
Hagoromo	Japan	1695	E. F. do Areeiro	Spain
Hikarugenji	Japan	1859	E. F. do Areeiro	Spain
Il Cigno	Italy	1845	E. F. do Areeiro	Spain
Il Giogello	Italy	1867	E. F. do Areeiro	Spain
Imbricata	China	1824	E. F. do Areeiro	Spain
Incarnata	China	1812	Pazo de Santa Cruz de Ribadulla	Spain
Justine Heurtin	France	1886	Castillo de Soutomaior	Spain
Latifolia	Belgium	1834	Pazo de La Saleta	Spain
Leeana Superba	Belgium	1834	Villa Anelli	Italy
Leonardo da Vinci	Italy	1888	Castillo de Soutomaior	Spain
Margherita Coleoni	Belgium	1865	E. F. do Areeiro	Spain
Marguerite Gouillon	France	1839	Pazo de Quintáns	Spain
Mathotiana	Belgium	1847	Villa Anelli	Italy
Mathotiana Alba	Belgium	1858	Villa Anelli	Italy
Mathotiana Rosea	UK	1874	Villa Anelli	Italy
Mont Blanc	Belgium	1843	Pazo de Santa Cruz de Ribadulla	Spain
Nobilissima	Belgium	1836	E. F. do Areeiro	Spain
Pompone	China	1815	Jardim Botanico de Porto	Portugal
Prince Eugene Napoleon	Belgium	1859	Pazo de Gandarón	Spain
Princesse Baciocchi	Italy	1842	E. F. do Areeiro	Spain
Roma Risorta	Italy	1866	Villa Anelli	Italy
Rubescens Major	France	1886	Pazo de La Saleta	Spain
Sacco	Italy	1839	Villa Anelli	Italy
Shiragiku (White Chrysanthemum)	Japan	1681	Pazo de La Saleta	Spain
Teutonia	Germany	1843	Palmengarten	Germany
Toki-no-hagasane	Japan	1879	E. F. do Areeiro	Spain
Tricolor	Japan	1829	Villa Anelli	Italy
Variegata	China	1792	Villa Anelli	Italy
Vergine di Collebeato	Italy	1846	Villa Anelli	Italy
Virginia Franco	Italy	1858	Villa Anelli	Italy
Vittorio Emanuelle II	Italy	1861	Villa Anelli	Italy

For the morphological characterization of the 17 old Spanish and Portuguese cultivars and the 18 cultivars of the Spanish living camellia germplasm collection, samples of flower, leaf and fruit (when available) were taken. Thirty-six morphobotanic descriptors were used: growth habit; in leaves: length, width, leaf area index, petiole length, blade shape, apex shape, base shape, margin and lamina color; in flowers: shape and diameter; in petals: number, form, margin, color, color distribution and venation; in petaloids: presence or absence, number, arrangement and variegation; in stamens: presence or absence, number, arrangement, filament color, anther color, union anther-filament, anther dehiscence, relative height androecium-gynoecium; and in fruits: presence or absence, number, texture and seed shape.

The 49 cultivars were characterized by microsatellite markers. Genomic DNA was extracted from frozen leaf samples by the EZNA High Performance Plant DNA Kit (Omega Biotek), according to the standard protocol recommended by the manufacturer. The DNA template of each sample was amplified with fourteen microsatellite markers, 7 proposed for 7 loci of the genomic DNA of C. japonica (Ueno et al., 1999, Abe et al., 2006) and other 7 for the genomic DNA of C. sinensis (Freeman et al., 2004; Hung et al., 2008; Zhao et al., 2008).

Following the method of Schuelke (2000), the forward primer of each microsatellite was labeled with one of the following fluorescent labels (fluorophores): 6-FAM, NED, PET and VIC (Applied Biosystems). The name, repeating pattern, sequences of forward and reverse primers and amplification conditions (temperature and annealing cycle time) of microsatellites are presented in

Table 2. Characteristics of the 14 microsatellite loci of Camellia japonica and Camellia sinensis, showing the repeat motif, sequences of each primer, annealing temperature, annealing cycle time, and expected allele size.

Micro satellites	Repeat motif	Primer sequences (5’→3’)	Tm (^oC)	Cycle time	Size expected (pb)
MSCjaF25	(CA)₈(AAAAAT)₄	F:GGGAAGGTGCATAAAATACT R:TGCGACCTAAGATTACTAAA	58	1 min	213-245
MSCjaF37	(AG)₁₃(GAA)₇	F:CGCTCGACGTAATGCCACACT R:CGAGCCTTCCTTTTCCCATTC	58	1 min	344-370
MSCjaH38	(GA)₁₄	F:CCTATTGCCTACGACCATTTC R:GCTGAGCTTGGAGATTTTGTT	55	1 min	343-362
MSCjaH46	(GA)₁₆	F:AGGGAGCATTATGAGTCGTCT R:CATCGTCCTAATCCACTTCAC	55	1 min	443-461
MSCjaQ11	(GA)₁₃	F:GCCTCCGATGCATTGGT R: CCACTATTTTGTTCCCTTGC	60	1 min	200-224
MSCjaR02	(CT)₈...(CT)₁₁	F:AAGGGTGATGCAAAAGTGAGA R: TTCTTTGGGTTGTGTTCCAA	55	1 min	219-248
MSCjaT25	(GA)₄...(GA)₁₈	F: CACAGTCTTCAAAACAACTT R: AGGACCTCACCCTTGTTGA	55	1 min	172-193
CamsinM5	(GT)₁₅(GA)₈	F:AAACTTCAACAACCAGCTCTGGTA R:AATTATAGGATGCAAACAGGCATGA	60	1 min	206-224
CamsinM11	(CA)₁₂	F:GCATCATTCCACCACTCACC R:GTCATCAAACCAGTGGCTCA	55	1 min	173-182
Ca01	(CAG)₆…(CAG)₅	F:CCCAGCAAAACCCCAGCATG R:CTTCCGAACTGCAGGTTGTGG	64/ 60	1 min	157-176
Ca06	(GT)₁₂(GA)₁₀	F:CATGTAGAATGCTCAAATGC R:ACCTGAAAACGATCCTGACAT	60	30 seg	237-362
Ca08	(CT)₁₀	F:TTCAATTACCCGCCAATCTC R:CCAATCTGGGAATTGAAGAAG	55	1 min	154-187
Z496	(AG)₁₁	F:GAAAGTGCGAAACCAAAC R:CTGCGAACCCTCTTGACC	55	1 min	102-122
Z641	(AGAGA)₃	F:CAAGCAATACATACACACA R:AACAGAGCATACCCAGAAG	60	30 seg	149-209

Amplification reactions by PCR were carried out in a final volume of 25 mL containing: 50 ng of genomic DNA, 0.08 mM of each primer, 1U Taq polymerase and 0.2 mM of each dNTP. PCR reactions were performed in a thermocycler Doppio (VWR). Amplification conditions were: 5 minutes at 95°C, 35 cycles: 1 minute at 95°C, between 30 seconds and one minute at the corresponding hybridization temperature (Tm) (temperature and hybridization cycle time for each microsatellite are shown in Table 2), 1 minute at 72°C, and a final step of 15 minutes at 72°C.

Stem cuttings from the 49 cultivars were used to propagate new plants that were then planted to initiate the first field germplasm bank of camellia reference cultivars at the Estación Fitopatolóxica do Areeiro (Pontevedra, NW Spain).

Results and Discussion

The morphological descriptors were useful tools for differentiating most of the Camellia japonica cultivars of the study (data not shown). However, some of them (like ‘Imbricata’ and ‘Princesse

Figure 1. Drawing of the Camellia cultivar ‘Imbricata’ (Chandler and Booth, 1831).

Figure 2. Drawing of the Camellia cultivar ‘Princesse Baciocchi’ (Berlese, 1843).

Baciocchi’, figures 1 and 2) share very similar flower features, being almost impossible to be properly identified from morphological characters. In addition, many of the cultivars of the study are indistinguisable from others of the more than 30,000 registered.

Our results show that the identification of an unknown cultivar of C. japonica can not always be achieved by making a comparison of the key descriptors of the morphological characteristics with known cultivar descriptions. It is therefore essential to use other techniques to complement the morphological characterization. The 14 microsatellite markers proved to be efficient for the differentiation of C. japonica cultivars, as they provide characteristic allelic profiles for each cultivar (data not shown). Allelic profiles were used as the main basis for the characterization and establishment of the first germplasm bank of camellia reference cultivars.

The application of microsatellite markers for producing robust and reliable cultivar descriptions, suitable for database use and largely unaffected by environment, can be a key tool to achieve distinctness from the large numbers of cultivars that could make up the reference collection of Camellia japonica cultivars in the future.

Acknowledgements

This work was funded by Xunta de Galicia (Project PGIDIT06RAG26103PR).
We thank Dr. Clemens Bayer and Dr. Andrea Corneo for sending us camellia samples.
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