Jude W. Grosser

Somatic hybridization in citrus: an effective tool to facilitate variety improvement.

SummaryCitrus somatic hybridization and cybridization via protoplast fusion has become an integral part of citrus variety improvement programs worldwide. Citrus somatic hybrid plants have been regenerated from more than 200 parental combinations, and several cybrid combinations have also been produced. Applications of somatic hybridization to citrus scion improvement include the production of quality tetraploid breeding parents that can be used in interploid crosses to generate seedless triploids, and the direct production of triploids by haploid + diploid fusion. Applications of somatic hybridization to citrus rootstock improvement include the production of allotetraploid hybrids that combine complementary diploid rootstocks, and to combine citrus with sexually incompatible or difficult to hybridize genera that possess traits of interest for germplasm expansion. A few somatic hybrid tetraploid breeding parents have flowered, are fertile, and are being used as pollen parents to generate triploids. Several allotetraploid somatic hybrid rootstocks are performing well in commercial field trials, and show great promise for tree size control. Seed trees of most of these somatic hybrid rootstocks are producing adequate nucellar seed for standard propagation. Somatic hybridization is expected to have a positive impact on citrus cultivar improvement efforts.

Intergeneric somatic hybrid plants from sexually incompatible woody species: Citrus sinensis and Severinia disticha

SummaryThe fusion of Citrus sinensis cv. Hamlin (sweet orange) protoplasts isolated from an embryogenic suspension culture with Severinia disticha (Philippine box orange) protoplasts isolated from epicotyl-derived callus with organogenic potential, resulted in the regeneration of allotetraploid somatic hybrid plants. Plant regeneration was a function of complementation, combining the capacity for somatic embryogenesis of C. sinensis with the organogenic ability of S. disticha. Confirmation of somatic hybrid identity was based on leaf morphology, chromosome number, and analyses of phosphoglucose mutase (PGM) and malate dehydrogenase (MDH) zymograms. Hybrid plants were multiplied organogenically and exhibited morphology intermediate to that of the parents. This is the first example of somatic hybrid plants produced between sexually incompatible woody genera.

Protoplast fusion for production of tetraploids and triploids: applications for scion and rootstock breeding in citrus

Protoplast fusion technology has been utilized in many crops to generate allotetraploid somatic hybrids, and sometimes autotetraploids as a byproduct of the process. A brief history of this technology development is provided, along with a simple protocol developed for citrus, which can be easily adapted to other plants. Protoplast fusion has become a significant tool in ploidy manipulation that can be applied in various cultivar improvement schemes. In rare cases, a new somatic hybrid may have direct utility as an improved cultivar; however, the most important application of somatic hybridization is the building of novel germplasm as a source of elite breeding parents for various types of conventional crosses for both scion and rootstock improvement. Somatic hybridization is generating superior allotetraploid breeding parents for use in interploid crosses to generate seedless triploids. Seedlessness is a primary breeding objective for new fresh fruit citrus varieties, and several thousand triploid hybrids have been produced using somatic hybrids as the tetraploid parent. Protoplast fusion is also being utilized to produce somatic hybrids that combine complementary diploid rootstocks, which have shown good potential for tree size control. Tree size control has gained importance as a means of reducing harvesting costs, maximizing the efficiency of modern cold protection methodology, and facilitating the adaptation of new fruit production systems. Successful somatic hybridization in citrus rootstock improvement has enabled rootstock breeding at the tetraploid level via sexual hybridization, which can yield maximum genetic diversity in zygotic progeny upon which to impose selection for the many traits required in improved rootstock cultivars, including disease and insect resistance, broad adaptation, tree size control, and the ability to consistently produce high yields of quality fruit. Recent progress and successful examples of these applications are discussed. Finally, a discussion of the genetic potential of somatic hybrids as breeding parents, including meiotic behavior and inheritance is provided.

An alternative method for the genetic transformation of sweet orange.

SummaryAn alternative method for transforming sweet organe [Citrus sinensis (L.) Osbeck] has been developed. Plasmid DNA encoding the non-destructive selectable marker enhanced green fluorescent protein gene was introduced using polyethylene glycol into protoplasts of ‘Itaborai’ sweet organe isolated from an embryogenic nucellar-derived suspension culture. Following protoplast culture in liquid medium and transfer to solid medium, transformed calluses were identified via expression of the green fluorescent protein, physically separated from non-transformed tissue, and cultured on somatic embryogenesis induction medium. Transgenic plantlets were recovered from germinating somatic embryos and by in vitro rooting of shoots. To expedite transgenic plant recovery, regenerated shoots were also micrografted onto sour orange seedling rootstocks. Presence of the transgene in calluses and regenerated sweet organe plants was verified by gene amplification and Southern analyses. Potential advantages of this transformation system over the commonly used Agrobacterium methods for citrus are discussed.

Further evidence of a cybridization requirement for plant regeneration from citrus leaf protoplasts following somatic fusion

SummarySomatic hybridization experiments in Citrus that involve the fusion of protoplasts of one parent isolated from either nucellus-derived embryogenic callus or suspension cultures with leaf-derived protoplasts of a second parent, often result in the regeneration of diploid plants that phenotypically resemble the leaf parent. In this study, plants of this type regenerated following somatic fusions of the following three parental combinations were analyzed to determine their genetic origin (nuclear and organelle): (embryogenic parent listed first, leaf parent second) (1) calamondin (C. microcarpa Bunge) + ‘Keen’ sour orange (C. aurantium L.), (2) Cleopatra mandarin (C. reticulata Blanco) + sour orange, and (3) ‘Valencia’ sweet orange (C. sinensis (L.) Osbeck) + ‘Femminello’ lemon (C. limon (L.) Burm. f.). Isozyme analyses of PGI, PGM, GOT, and IDH zymograms of putative cybrid plants, along with RFLP analyses using a nuclear genome-specific probe showed that these plants contained the nucleus of the leaf parent. RFLP analyses using mtDNA-specific probes showed that these plants contained the mitochondrial genome of the embryogenic callus donor, thereby confirming cybridization. RFLP analyses using cpDNA-specific probes revealed that the cybrid plants contained the chloroplast genome of either one or the other parent. These results support previous reports indicating that acquisition of the mitochondria of embryogenic protoplasts by leaf protoplasts is a prerequisite for recovering plants with the leaf parent phenotype via somatic embryogenesis following somatic fusion.

Intergeneric somatic hybrid plants of Citrus sinensis cv. Hamlin and Poncirus trifoliata cv. Flying Dragon.

Intergeneric somatic hybrid plants between ‘Hamlin’ sweet orange [Citrus sinensis (L.) Osbeck] and ‘Flying Dragon’ trifoliate orange (Poncirus trifoliata Raf.) were regenerated following protoplast fusion. ‘Hamlin’ protoplasts, isolated from an habituated embryogenic suspension culture, were fused chemically with ‘Flying Dragon’ protoplasts isolated from juvenile leaf tissue. The hybrid selection scheme was based on complementation of the regenerative ability of the ‘Hamlin’ protoplasts with the subsequent expression of the trifoliate leaf character of ‘Flying Dragon.’ Hybrid plants were regenerated via somatic embryogenesis and multiplied organogenically. Hybrid morphology was intermediate to that of the parents. Chromosome counts indicated that the hybrids were allotetraploids (2n=4x=36). Malate dehydrogenase (MDH) isozyme patterns confirmed the hybrid nature of the regenerated plants. These genetically unique somatic hybrid plants will be evaluated for citrus rootstock potential. The cell fusion, selection, and regeneration scheme developed herein should provide a general means to expand the germplasm base of cultivated Citrus by intergeneric hybridization with related sexually incompatible genera.

Allotetraploid hybrids between citrus and seven related genera produced by somatic hybridization

We have developed an efficient protoplast-fusion method to produce somatic hybrid allopolyploid plants that combine Citrus with seven related genera, including four that are sexually incompatible. In this paper we report the creation of 18 new allotetraploid hybrids of Citrus, including ten among sexually incompatible related genera, that may have direct cultivar potential as improved citrus rootstocks. All hybrids were confirmed by cytological and RAPD analyses. If fertile, the attributes of these hybrids may be amenable to further genetic manipulation by breeding at the tetraploid level. Wide somatic hybridization of Citrus via protoplast fusion bypasses biological barriers to the natural allopolyploidization of Citrus, and creates new evolutionary opportunities that would be difficult or impossible to achieve by natural or conventional hybridization.

Intergeneric somatichhybrid plants from protoplast fusion of Fortunella crassifolia cultivar ‘Meiwa’ with Citrus sinensis cultivar ‘Valencia’☆

Abstract Leaf-derived protoplasts isolated from in vitro grown seedlings of Fortunella crassifolia Swing cultivar ‘Meiwa’ were fused chemically with protoplasts isolated from embryogenic suspension cultures of Citrus sinensis (L.) Osbeck cultivar ‘Valencia’. Protoplasts were cultured following fusion, and mitosis was first observed after 10 days incubation in the dark at 28°C. Embryoids were recovered from regenerated calli 2 weeks after transfer to agar-solidified medium. Cytological evaluation of 27 embryoids revealed seven tetraploids and 20 diploids. Embryos were germinated and shoots dissected from germinated embryos were rooted in vitro. Counts of chromosomes in cells of young leaf meristems indicated that most regenerated plants were tetraploid (2n = 4x = 36). Peroxidase (PER) leaf isozyme banding patterns confirmed the somatic hybridity of recovered tetraploids. More than 50 somatic hybrid plants have been recovered and successfully acclimated.

Non-random inheritance of mitochondrial genomes in Citrus hybrids produced by protoplast fusion

Abstract. Somatic hybridization offers the possibility of manipulating chloroplast and mitochondrial genomes and evaluating their role on cultivar qualities in citrus. Numerous associations between Willow-leaf mandarin (Citrus deliciosa Ten.), as embryogenic parent, and sweet orange cv. Valencia (Citrus sinensis (L.) Osb.), as mesophyll parent, and between Willow-leaf mandarin (embryogenic parent) and grapefruit cv. Duncan (Citrus paradisi Macf.) (mesophyll parent) were obtained by the fusion of protoplasts induced by polyethylene glycol. Regenerated plants were characterized by flow cytometry and nuclear and mitochondrial DNA restriction fragment length polymorphism (RFLP). All plants were diploid. Diploid plants with the nuclear RFLP patterns of mandarin or sweet orange were identified in the progeny between these two parents, while only grapefruit nuclear types were found in the mandarin + grapefruit progeny. The diploid plants with the nuclear profile of the mesophyll parent originated systematically from cells formed through spontaneous association of the nuclear genome of the mesophyll parent and the mitochondrial genome of the embryogenic parent. These plants are assumed to be alloplasmic hybrids or cybrids. They were viable and have been propagated for field testing.

Somatic hybrid plants from sexually incompatible woody species Citrus reticulata and Citropsis gilletiana

SummaryAllotetraploid intergeneric somatic hybrid plants between Citrus reticulata Blanco cv. Cleopatra mandarin and Citropsis gilletiana Swing. & M. Kell. (common name Gillets cherry orange) were regenerated following protoplast fusion. Cleopatra protoplasts were isolated from an ovule-derived embryogenic suspension culture and fused chemically with leaf-derived protoplasts of Citropsis gilletiana. Cleopatra mandarin and somatic hybrid plants were regenerated via somatic embryogenesis. Hybrid plant identification was based on differential leaf morphology, root-tip cell chromosome number, and electrophoretic analyses of phosphoglucose mutase (PGM) and phosphohexose isomerase (PHI) isozyme banding patterns. This is the first somatic hybrid within the Rutaceae reported that does not have Citrus sinensis (sweet orange) as a parent, and the first produced with a commercially important citrus rootstock and a complementary but sexually incompatible, related species.