Assessment of genetic and phenotypic diversity of the giant kelp, Macrocystis pyrifera, to support breeding programs

Camus, Carolina; Faugeron, Sylvain; Buschmann, Alejandro H.

doi:10.1016/j.algal.2018.01.004

Cited by 36 publications

(25 citation statements)

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“…The genetic structuring appears to be affected both by spread via ocean currents (Mooney et al, 2018) and by environmental variation and local adaptation (Nielsen et al, 2016). Similar studies of M. pyrifera populations along stretches of the American Pacific coast also identified several distinct genetic groups and suggested that both ocean currents and local adaptation to different environments can be important for this grouping (Alberto et al, 2011;Johansson et al, 2015;Camus et al, 2018).…”

Section: Invasiveness Introduction Of Non-native Genotypes and Gene mentioning

confidence: 66%

“…Other peculiar modes of reproduction that can occur in Laminariales include apogamy, where a haploid sporophyte can emerge directly from a somatic cell of a gametophyte (Nakahara and Nakamura, 1973;Fang, 1984;Wu and Lin, 1987;Müller et al, 2019) (Figure 1C), and apospory, where a diploid gametophyte can develop from vegetative cells of a diploid sporophyte without any meiosis or spore formation (Nakahara and Nakamura, 1973;Lewis et al, 1993) (Figure 1D). Self-fertilization appears to be possible in most studied species of Laminariales (Wu and Lin, 1987;Brawley and Johnson, 1992;Kraan et al, 2000;Camus et al, 2018). Some kelp species are annual or biennial, but most are perennial (Schiel and Foster, 2006).…”

Section: Kelp Life Cyclesmentioning

confidence: 99%

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Cultivar Development of Kelps for Commercial Cultivation—Past Lessons and Future Prospects

2020

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Cultivated kelps and other macroalgae have great potential in future provision of food, feed, bioenergy, fertilizer, and raw material for a range of chemical products including pharmaceuticals, food and feed additives, and cosmetics. Only a few species are currently cultivated, almost exclusively in Asia. There is a range of species that could be utilized in different parts of the world, providing that protocols for reproduction, propagation, and cultivation are developed. Domestication of species involves selection of traits that are desirable in cultivation and in the utilization of the harvested biomass. Genetic improvement of cultivated species through recombination of alleles and selection (breeding) has ensured high productivity and product quality in both agri-and aquaculture and will likely do so for macroalgae cultivation and use as well. According to the published literature, genetic improvement of kelps in Asia has so far largely relied on utilization of heterosis expressed in certain combinations of parental material, sometimes species hybrids. Here, we explore and evaluate the various methods that could be used in kelp breeding and propose an initial simple and low-cost breeding strategy based on recurrent mixed hybridization and phenotypic selection within local populations. We also discuss the genetic diversity in wild populations, and how this diversity can be protected against genetic pollution, either by breeding and cultivating local populations, or by developing cultivars that are not able to establish in, or hybridize with, wild populations.

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Section: Invasiveness Introduction Of Non-native Genotypes and Gene mentioning

confidence: 66%

Section: Kelp Life Cyclesmentioning

confidence: 99%

Cultivar Development of Kelps for Commercial Cultivation—Past Lessons and Future Prospects

2020

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“…Despite a fast-growing interest in commercial aquaculture, corresponding with a rapidly increasing global demand for nutrition supplementation and industry raw material, few researchers outside of Asia have explored sustainable domestication programs, including the creation of macroalgae germplasm banks [31,39,75,76]. Several facilities, such as the National Institute of Fisheries Science-Seaweed Research Center in South Korea and the Ocean University of China and Chinese Academy of Science, have dedicated infrastructure and research to the maintenance of commercially important macroalgal species and cultivars.…”

Section: International Cooperation and Collaboration Are Necessary Fomentioning

confidence: 99%

Macroalgal germplasm banking for conservation, food security, and industry

et al. 2020

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Ex situ seed banking was first conceptualized and implemented in the early 20th century to maintain and protect crop lines. Today, ex situ seed banking is important for the preservation of heirloom strains, biodiversity conservation and ecosystem restoration, and diverse research applications. However, these efforts primarily target microalgae and terrestrial plants. Although some collections include macroalgae (i.e., seaweeds), they are relatively few and have yet to be connected via any international, coordinated initiative. In this piece, we provide a brief introduction to macroalgal germplasm banking and its application to conservation, industry, and mariculture. We argue that concerted effort should be made globally in germline preservation of marine algal species via germplasm banking with an overview of the technical advances for feasibility and ensured success. Macroalgae are essential members of marine communities and are no exception to the threats of climate change Worldwide, biodiversity is declining at alarming rates, resulting in what some scholars are calling the Earth's sixth great extinction event [1]. The marine environment is no exception, with increasing sea surface temperatures leading to drastic alterations in marine populations, communities, and ecosystems [2,3]. Of particular concern is potential for loss of macroalgae (defined as benthic eukaryotic algae of at least 1 mm in length [4]), which function as ecological engineers [5-9], primary producers [3,10], habitat and structure providers [6], nutrient cyclers, keystone species [11], food and nursery grounds for invertebrates and pelagic organisms, and shoreline buffers from storms [12,13]. Furthermore, macroalgae are a US$11 billion industry as food, animal feed, and fertilizers [14-16]. Seaweeds are under threat from multiple stressors including warming sea surface temperatures, pollution, overharvesting, and other anthropogenic disturbances that have major consequences for the structure and function of near-shore coastal ecosystems [13,17]. Although seaweeds are predicted to function photosynthetically well with increases in CO 2 [18,19], their distributions within their local communities (i.e., occupied tidal zone) and globally (i.e., latitudinal range) are likely to be impacted by

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“…, Camus et al. ) as well as their historical phylogeographic diversification (e.g., Tellier et al. , Buonomo et al.…”

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confidence: 99%

“…In macroalgae, most genetic studies are focused on the population and regional levels and have mainly dealt with resolving the taxonomy of seaweeds and their phylogenetic relationships (e.g., Ragan et al 1994, De Clerck et al 2005, Gonz alez et al 2012, Leliaert et al 2012, Verbruggen et al 2016, Steen et al 2017. Moreover, researchers have studied the population genetics of seaweeds with a focus on genetic variability and its distribution within and among populations (e.g., Valero et al 2001, Mart ınez et al 2003, Guillemin et al 2008, Wang et al 2008, Andreakis et al 2009, Alberto et al 2010, Krueger-Hadfield et al 2011, Camus et al 2018) as well as their historical phylogeographic diversification (e.g., Tellier et al 2009, Buonomo et al 2017, Neiva et al 2018). Few studies have assessed different levels of genetic diversity in macroalgae.…”

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confidence: 99%

Intraorganismal genetic heterogeneity as a source of genetic variation in modular macroalgae

Santelices

Gallegos

González

2018

Journal of Phycology

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Genetic diversity is considered a key factor of population survival and evolution, especially in changing environments. Genetic diversity arises from mutations in the DNA sequence of cell lines and from there it reaches the level of organisms, populations, and regions. However, many previous studies have not considered the organism architecture or pattern of thallus construction, ignoring the potential genetic complexities that intraorganismal genetic heterogeneity could generate in modular organisms. In seaweeds, modularity and clonality exist in many species. Modular organization has been related to advantages in terms of rapid construction and recovery after the loss of individual modules, which have their own demographic properties as they generate, mature, senesce, and die. Based on recent evidence from the literature, we suggest that modules also have their own genetic properties. Specifically, modular seaweeds have two possible sources of genetic diversity at the individual level: the heterozygosity of the genotypes composing the genet, and genetic heterogeneity among the modules within a genet (i.e., intraclonal genetic variability). Both sources of genetic diversity can have ecological and evolutionary consequences, and most of them must be considered in research on modular seaweeds. Linking intraorganismal genetic diversity with clonal architecture and propagation styles may help us to understand important ecological and evolutionary processes such as speciation modes, invasive capacities, or farming potential.

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Assessment of genetic and phenotypic diversity of the giant kelp, Macrocystis pyrifera, to support breeding programs

Cited by 36 publications

References 72 publications

Cultivar Development of Kelps for Commercial Cultivation—Past Lessons and Future Prospects

Cultivar Development of Kelps for Commercial Cultivation—Past Lessons and Future Prospects

Macroalgal germplasm banking for conservation, food security, and industry

Intraorganismal genetic heterogeneity as a source of genetic variation in modular macroalgae

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