François-Xavier Côte

Bio: François-Xavier Côte is an academic researcher from Centre de coopération internationale en recherche agronomique pour le développement. The author has contributed to research in topics: Somatic embryogenesis & Musaceae. The author has an hindex of 18, co-authored 64 publications receiving 1447 citations. Previous affiliations of François-Xavier Côte include Centro Agronómico Tropical de Investigación y Enseñanza.

Comparison of methods of liquid medium culture for banana micropropagation : effects of temporary immersion of explants

Abstract: Five different liquid medium culture methods for meristem propagation of bananas were investigated and compared with solid medium culture. Treatments studied were: gelled culture medium (treatment 1); liquid medium with immersion of the plants (treatment 2); liquid medium with cellulose culture support (treatment 3); liquid medium with partial immersion of the plants (treatment 4); liquid medium aerated by bubbling (treatment 5); liquid medium with temporary immersion of the explants for 20 min every 2 h (treatment 6). After 20 days of culture, three culture groups with statistically different multiplication rates were observed: - shoots in simple liquid medium and those on cellulose substrate proliferated little or not at all, - shoots on gelled medium, those subjected to partial immersion and those in aerated medium displayed multiplication rates of 2.2 to 3.1, and - the highest multiplication rate (>5) was observed in explants subjected to temporary immersion in the medium. Two groups of treatments differed in the accumulation of dry matter: the smallest weight (around 0.5 g) was observed in treatments 1, 2, 3 and 4, and accumulation was 2 to 5 times greater in the explants in aerated liquid medium and those subjected to temporary immersion. The highest multiplication rates and weight gains were observed in aerated treatments (treatments 4 and 5). Shoots in liquid medium continuously aerated by bubbling displayed hyperhydricity of the outer leaf sheaths. This was not observed with temporary immersion of explants. (Resume d'auteur)

Embryogenic cell suspensions from the male flower of Musa AAA cv. Grand nain

Abstract: There are very few reports on the establishment of long-term embryogenic cell cultures of banana, especially of triploid cultivars of commercial interest. Embryogenic cell suspensions were prepared using the cultivar Grand nain, the most widely grown dessert banana in the world. After culture for 5 or 6 months of immature male flowerbuds adjacent to the floral apex, yellow, compact calluses and white, friable embryogenic tissues were induced. Suspension cultures were initiated from embryogenic tissues placed in liquid medium. The packed cell volume (PCV) of the suspensions increased 2- to 5- fold with each monthly culture cycle. Plating of the embryogenic suspensions resulted in approximately 370×103 embryos per ml of PCV. Depending on the size of embryos, 3 to 20% germination was observed. A histological survey of cell suspensions and embryo development was carried out. Cellular aggregates with cells displaying typical embryogenic features were formed. Most of the somatic embryos were probably of unicellular origin.

Amplified somatic embryogenesis from male flowers of triploid banana and plantain cultivars (Musa spp.)

Abstract: Somatic embryogenesis and plant regeneration of banana and plantain cultivars (Musa spp) were obtained by culturing young male flowers Multiplication and maintenance of embryogenic cultures were achieved by culturing somatic embryos in a temporary immersion system (SIT) A multiplication rate of 40 allowed us to obtain more than 6000 somatic embryos after 6 mo of subculture Plant recovery frequencies were 60 to 70% This method was expanded to different banana and plantain genomic groups

Recovery and regeneration of embryogenic cultures from female flowers of False Horn Plantain.

Abstract: Somatic embryogenesis from immature male flowers in Musa is only suitable for genotypes with a male bud. Six friable embryogenic cultures were obtained from 28 cultured buds of female flowers of the AAB False Horn Plantains, ‘Currare’ and ‘Currare Enano’. Embryogenic suspensions were established from these embryogenic cultures. Somatic embryogenesis was demonstrated histologicaly. Regeneration of plants was obtained either from somatic embryos directly isolated from embryogenic cultures or from suspensions after plating on a semi-solid medium. This study demonstrates that somatic embryogenesis from immature flowers is suitable for genotypes of Musa with or without male buds.

Plant regeneration from protoplasts of dessert banana cv. Grande Naine (Musa spp., Cavendish sub-group AAA) via somatic embryogenesis

Abstract: Protoplast culture and plant regeneration of the dessert banana cultivar Grande Naine (Musa spp., Cavendish sub-group AAA) were achieved through somatic embryogenesis. Protoplasts were isolated from cell suspensions at a yield of 3×107 protoplasts/ml packed cell volume (0.5 g). For the induction of cell divisions, two banana cell suspensions, SF265 (AA) and IRFA903 (AA), were used as feeder layers. SF265 (AA) was found to be more efficient for inducing cell divisions than IRFA903 (AA). The first embryogenic cell suspensions were established from protoplast-derived microcalli. The transfer of microcalli and protoplast-derived cell suspensions onto regeneration medium containing plant growth regulators slightly increased the number of embryos relative to those maintained on a feeder layer with growth regulators. Plant regeneration was achieved in the same regeneration medium.

The Theory of Island Biogeography

Abstract: Preface to the Princeton Landmarks in Biology Edition vii Preface xi Symbols Used xiii 1. The Importance of Islands 3 2. Area and Number of Speicies 8 3. Further Explanations of the Area-Diversity Pattern 19 4. The Strategy of Colonization 68 5. Invasibility and the Variable Niche 94 6. Stepping Stones and Biotic Exchange 123 7. Evolutionary Changes Following Colonization 145 8. Prospect 181 Glossary 185 References 193 Index 201

Somaclonal variation in plants: causes and detection methods

Abstract: Plant tissue culture has become one of the fundamental tools of plant science research. It is extensively employed in the production, conservation and improvement of plant resources. The presence of somaclonal variation in populations derived from tissue culture is affecting the use of tissue culture negatively and has remained a major problem. Conversely, it is a source of new desirable clones/variants with better agronomic traits. In this review, we summarize the possible causes, detection methods and desirability of variants. Somaclonal variation is one of the most researched and reviewed topics. Hence, we restricted ourselves to outlining various examples which may be used as important references for researchers who intend to identify and/or characterize somaclonal variants while using tissue culture for research and production. Emphasis is placed on the negative effects of somaclonal variation. However, this review also includes examples of some useful variants generated as a result of somaclonal variation.

Plant cryopreservation: Progress and prospects

Abstract: Cryopreservation (liquid nitrogen, −196°C) represents the only safe and cost-effective option for long-term conservation of germplasm of non-orthodox seed species, vegetatively propagated species, and of biotechnology products. Classical cryopreservation techniques, which are based on freeze-induced dehydration, are mainly employed for freezing undifferentiated cultures and apices of cold-tolerant species. New cryopreservation techniques, which are based on vitrification of internal solutes, are successfully employed with all explant types, including cells suspensions and calluses, apices, and somatic and zygotic embryos of temperate and tropical species. The development of cryopreservation protocols is significantly more advanced for vegetatively propagated species than for recalcitrant seed species. Even though its routine use is still limited, there are a growing number of examples where cryopreservation is employed on a large scale for different types of materials, including seeds with orthodox and intermediate storage behaviour, dormant buds, pollen, biotechnology products, and apices sampled from in vitro plantlets of vegetatively propagated species. Cryopreservation can also be employed for uses other than germplasm conservation, such as cryoselection, i.e., the selection through freezing of samples with special properties, or cryotherapy, i.e., the elimination of viruses from infected plants through apex cryopreservation. Because of its high potential, it is expected that cryopreservation will become more frequently employed for long-term conservation of plant genetic resources.

Temporary immersion systems in plant micropropagation

Abstract: Temporary immersion systems for plant micropropagation have been described and grouped into 4 categories according to operation: tilting and rocker machines; complete immersion of plant material and renewal of the nutrient medium; partial immersion and a liquid nutrient renewal mechanism; complete immersion by pneumatic driven transfer of liquid medium and without nutrient medium renewal. The positive effects of temporary immersion on micropropagation are indicated for shoot proliferation and microcuttings, microtuberization and somatic embryogenesis. Immersion time, i.e. duration or frequency, is the most decisive parameter for system efficiency. Optimizing the volume of nutrient medium and the volume of the culture container also substantially improves efficacy, especially for shoot proliferation. Temporary immersion also generally improves plant material quality. It results in increased shoot vigour and in the frequency of morphologically normal somatic embryos. Hyperhydricity, which seriously affects cultures in liquid medium, can be eliminated with these culture systems or controlled by adjusting the immersion times. Plant material propagated by temporary immersion can perform better during the acclimatization phase than material obtained on semi-solid or in liquid media. Successful regeneration of plants, after direct sowing on soil of Solanum tuberosum microtubers and Coffea arabica somatic embryos produced in temporary immersion bioreactors, has been demonstrated. As could be expected when using liquid medium for micropropagation, several estimations confirm large gains in efficacy from temporary immersion. The parameters most involved in reducing production costs include: (1) the drastic reduction in work; (2) reduction in shelving area; (3) reduction in the number of containers used; (4) better biological yields. Scaling-up somatic embryogenesis and shoot proliferation procedures involving temporary immersion systems in order to commercialize this process are now taking place.

Use of biotechnologies for the conservation of plant biodiversity

Abstract: In vitro techniques are very useful for conserving plant biodiversity, including (a) genetic resources of recalcitrant seed and vegetatively propagated species, (b) rare and endangered plant species and (c) biotechnology products such as elite genotypes and genetically engineered material. Explants from recalcitrant seed and vegetatively propagated species can be efficiently collected under field conditions using in vitro techniques. In vitro culture techniques ensure the production and rapid multiplication of disease-free material. Medium-term conservation is achieved by reducing growth of plant material, thus increasing intervals between subcultures. For long-term conservation, cryopreservation (liquid nitrogen, −196°C) allows storing plant material without modification or alteration for extended periods, protected from contaminations and with limited maintenance. Slow growth storage protocols are routinely employed for a large number of species, including numerous endangered plants, from temperate and tropical origin. Cryopreservation is well advanced for vegetatively propagated species, and techniques are ready for large-scale experimentation in an increasing number of cases. Research is much less advanced for recalcitrant species due to their seed characteristics, viz., very high sensitivity to desiccation, structural complexity and heterogeneity in terms of developmental stage and water content at maturity. However, various technical approaches should be explored to develop cryopreservation techniques for a larger number of recalcitrant seed species. A range of analytical techniques are available, which allow understanding physical and biological processes taking place in explants during cryopreservation. These techniques are extremely useful to assist in the development of cryopreservation protocols. In comparison with crop species, only limited research has been performed on cryopreservation of rare and endangered species. Even though routine use of cryopreservation is still limited, an increasing number of examples where cryopreservation is used on a large scale can be found both in genebanks for crops and in botanical gardens for endangered species.