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Seaweed diversity in Vietnam, with an emphasis on the brown algal genus Sargassum
Nguyen, V.Tu (2014). Seaweed diversity in Vietnam, with an emphasis on the brown algal genus Sargassum. PhD Thesis. Ghent University Faculty of Sciences, Department of Biology, Phycology Research Group: Gent. 191 pp.

Thesis info:

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Document type: Dissertation

Keywords
    Flora > Weeds > Marine organisms > Seaweeds
    Sargassum C.Agardh, 1820 [WoRMS]
    ISEW, Viet Nam [Marine Regions]
    Marine/Coastal

Author  Top 
  • Nguyen, V.Tu

Abstract
    Vietnam, a country in South-East Asia, is characterized by a coastline nearly 3300 km long. The coast; stretching from Gulf of Tonkin in the North to the gulf of Thailand in the South, has a predominant North-South orientation resulting in a rich and varied coastal environment. The people in Vietnam have traditionally relied on the rich coastal resources, first by harvesting natural populations and more recently by implementing aquaculture practices. Next to fish and shellfish, marine seaweeds (macroalgae) have traditionally been harvested among most of the Vietnamese coast. A survey of the uses of Vietnamese seaweeds results in 82 species which are considered economically valuable (Chapter 1). Many of these seaweeds are used for human consumption, while others have a role in traditional medicine or are used for colloid extraction (e.g. agar, carrageenan) or as feed for animals. Contrary however to neighboring countries such as China, the Philippines and Indonesia where seaweed mariculture has been seriously developed over the last decades, culturing seaweeds remains a largely marginal activity in Vietnam. Reasons as to why seaweed mariculture has not taken off as compared to the neighboring countries are at least partly to be found in the absence of a phycolloid industry in Vietnam. Instead Vietnam exports large amounts of raw seaweeds, harvested from natural populations, at a low price, and then imports the purified phycocolloids at a much higher price. A steadily growing demand for seaweed-derived products results in an increasing pressure on coastal ecosystems which risk overharvesting of natural populations. This risk is especially eminent for the brown algal genus Sargassum of which approximately 50.000 wet tons is harvested every year. Sargassum represents an important ecosystem engineering species of subtidal coastal habitats. The plants can grow easily up to 3-4 m in length and form dense vegetations with a major nursery function for countless juvenile vertebrate and invertebrate species. If plants, the uprights at least are annual, are harvested before becoming fertile, this may reduce the rejuvenation of natural populations and eventually lead to habitat degradation. Despite the value of seaweeds for humans as well as their role in coastal ecosystems in Vietnam, relatively little is known about them. Basic information on for example the number of species present and their distributions is not easily available. Most information on seaweeds is scattered in local literatures, written in Vietnamese. Thereto, we compiled a checklist of Vietnamese seaweeds (Chapter 2). A total of 827 species are reported (412 Rhodophyta, 180 Chlorophyta, 147 Phaeophyceae, 88 Cyanobacteria. This species richness is comparable to that of the Philippines and considerably higher than Taiwan, Thailand or Malaysia. A comparison of the species composition with neighbouring countries yielded surprisingly low similarities. Rather than an indication of a biogeographical pattern, we are of the opinion that the low similarity with neighboring countries is primarily an artifact resulting from taxonomic inconsistencies. The checklist could serve as a valuable tool, to reveal the seaweed diversity in Vietnam and to stimulate intraregional comparative research. Sargassum with 70 species and intraspecific taxa is undoubtedly the most species-rich seaweed genus in Vietnam (Chapter 3). The estimate of Sargassum diversity is however entirely based on interpretations of the morphological characters such as the base, secondary axes, the leaves, vesicles and receptacles. Therefore we reassessed Sargassum diversity based on molecular gene sequence data of the internal spaces of the ribosomal cistron (ITS rDNA) (Chapter 4). Although successful at higher taxonomic levels, subgenera and sections, the resolution of the ITS marker was not sufficient to point species boundaries with confidence. Many morphologically distinct ‘species’ were characterized by virtually identical ITS sequences. Conversely, specimens identified on morphological criteria as one ‘species’ were resolved in different clades. Results could be interpreted in two possible ways. First, traditional species concepts in Sargassum have been too broadly defined and the genus contains far less species. Alternatively, species in Sargassum result from a recent radiation and even the highly variable ITS region does not display enough variation to resolve the relationship among them. To address these outstanding questions we explored to use of Restriction site Associated DNA Sequences (RAD-Seq) to generate a set of highly variable nuclear markers. RAD-sequencing is a Next Generation Sequencing-based technique that generates thousands to hundreds of thousands DNA fragments that can be scored for Single Nucleotide Polymorphisms (SNPs) which in turn can be compared between individuals. RAD markers can be used to pinpoint loci under selection, or are used as neutral markers to reconstruct phylogeographical patterns or elucidate phylogenetic relationships among closely related species. During the experiment we generated more than 21 million sequences which after quality control and analyses in Stacks and SiLiX yielded 231 alignments which could potentially be used to address species boundaries in the genus Sargassum. The development of more than 200 markers presents a more than significant increase over markers used in traditional studies which generally combine one or two mitochondrial and/or chloroplast markers with sequences from the ribosomal cistron. It also boosts the number of potential markers by a factor 10 to 20 compared to microsatellite-based studies. Despite these results, there are issues that remain to be solved. For example, the libraries of the individual specimens are highly unequal in size. Some specimens are represented by 1.5 million sequences while others only have barely 800 sequences. We believe the main reason why some specimens are underrepresented is due to insufficient DNA quality. Therefore, future studies should focus on obtaining high quality DNA from Sargassum. A second issue is posed by the presence of multiple alleles in the final alignments. Normally one would expect 2 alleles per marker for a diploid organism. Our final alignments often contain more than 2 alleles per specimen. It is unclear at present if this is a technical issue which could eventually be solved by fine-tuning the parameters of the Stacks analyses or whether the multiple alleles issue has an underlying biological cause (polyploidisation). Despite these issues, RAD Sequencing has a great potential for population based molecular studies in algae. A selection of the current stacks can be used for primer design which can then be used to score markers by PCR followed by traditional Sanger sequencing. This approach can easily increase the number of nuclear markers for phylogeographic or species delimitation studies by a factor ten. Modest as it may be, I hope that by providing a compilation of the seaweed diversity in Vietnam and their economical importance, and by introducing DNA-based methodologies to assess species diversity in the ecologically and economically important genus Sargassum, I have contributed to the foundation for a sustainable exploitation of natural resources and continuous integrity of marine habitats.

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