Phylogenetic Inferences Reveal a Large Extent of Novel Biodiversity in Chemically Rich Tropical Marine Cyanobacteria

Engene, Niclas; Gunasekera, Sarath P.; Gerwick, William H.; Paul, Valerie J.

doi:10.1128/aem.03793-12

Cited by 67 publications

(94 citation statements)

References 51 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Although some cyanobacteria, such as Synechococcus sensu lato, lack phenotypic variability, great ecological and genetic diversity suggest that polyphyletic complexes of cryptic taxa might exist (Honda et al 1999;Robertson et al 2001;Dvořák et al 2014a, b). Many traditional cyanobacterial genera (Geitler 1932) are polyphyletic (Komárek 2010;Engene et al 2011;Hašler et al 2012;Engene et al 2013;Dvořák et al 2014a, b;Hašler et al 2014a) and need extensive revisions, which will be very difficult particularly in the case of Synehococcus sensu lato due to extreme polyphyly within this genus. We suggest that this extreme polyphyly (cryptogenera sensu Komárek et al 2014) should be distinguished from polyphyly in the original sense, since in extreme polyphyly a large number of lineages derived over very long time period (over 3 billion years), as shown in Dvořák et al (2014b).…”

Section: Particular Problems Of Species Definitions and Concepts In Cmentioning

confidence: 99%

Species concepts and speciation factors in cyanobacteria, with connection to the problems of diversity and classification

et al. 2015

View full text Add to dashboard Cite

The cyanobacteria are the most important prokaryotic primary producers on Earth, inhabiting a great diversity of aquatic and terrestrial environments exposed to light. However, the evolutionary forces leading to their divergence and speciation remain largely enigmatic compared to macroorganisms due to their prokaryotic nature, including vast population sizes, and largely asexual reproduction. The advent of modern molecular techniques has facilitated an understanding of the important factors shaping cyanobacterial evolution, including horizontal gene transfer and homologous recombination. We review the forces shaping the evolution of cyanobacteria and discuss the role of cohesive forces on speciation. Further, while myriad species concepts and definitions are currently used, only a limited subset might be applied to cyanobacteria due to their asexual reproduction. Additionally, concepts based solely on phenotypes provide insufficient resolution. A monophyletic species concept which is universal may be ideal for cyanobacteria. Actual identification of the cyanobacteria is difficult due to cryptic diversity, lack of morphological variability, and frequent convergent evolutionary events. Thus, applied molecular techniques such as DNA barcoding will be useful for identifications of environmental samples. Lastly, we show that the real biodiversity of the cyanobacteria is widely underestimated, due in part to low sampling efforts, sensitivity to the molecular markers 123Biodivers Conserv (2015) 24:739-757 DOI 10.1007 employed, and the species definitions employed by researchers. In conclusion, we anticipate a rapid increase in cyanobacterial taxa described and large revisions of the system in the future as scientists adopt a common approach to cyanobacterial systematics.

show abstract

Section: Particular Problems Of Species Definitions and Concepts In Cmentioning

confidence: 99%

Species concepts and speciation factors in cyanobacteria, with connection to the problems of diversity and classification

et al. 2015

View full text Add to dashboard Cite

show abstract

“…To date, however, there are no reports of marine cyanobacterial blooms in the Colombian Caribbean (particularly planktonic blooms), although several species have been recorded in floristic lists in the region (Díaz-Pulido & Díaz-Ruíz 2003, Reyes et al 2013. Benthic cyanobacterial mats in Old Providence, consisted of complex consortia belonging to the genera Okeania, Lyngbya, Symploca, Phormidium and Oscillatoria which have also been reported in other tropical areas (Hamisi et al 2004, Thacker & Paul 2004, Charpy et al 2010, Engene et al 2013a. At Old Providence Island, as well as in other Colombian Caribbean reefs off the continental shelf such as Rosario Islands and Barú, cyanobacteria have become more conspicuous, frequently surpassing live coral cover (Puyana M & Acosta A, unpub.…”

Section: Discussionmentioning

confidence: 99%

“…For the purposes of this paper we report the most common taxa found during field surveys after Komárek & Anagnostidis (2005) and Engene et al (2013b). During the period between 2011 and 2014 there has been a profound reevaluation of the group systematics beyond genera reassignment, showing great genetic diversity, and wide morphological and chemical variation (Thacker & Paul 2004, Engene et al 2010, Engene et al 2011, Engene et al 2013a, Engene et al 2013b). Blooms of marine benthic cyanobacteria are not monospecific and "accurate" species identification involves molecular and chemotaxonomical analyses.…”

Section: Samplingmentioning

confidence: 99%

Spatial scale of cyanobacterial blooms in Old Providence Island, Colombian Caribbean

Puyana

Acosta²,

Bernal-Sotelo³

et al. 2014

Univ. Sci.

View full text Add to dashboard Cite

Cyanobacterial blooms have increased in coastal waters worldwide, facilitated by excessive nutrient input and apparently global warming. They exert negative consequences in marine ecosystems, communities and habitats. Although reports of these events are frequent, their spatial extent and affected habitats are not completely recognized, hence restricting regional management actions. We examined the presence, spatial scale and cover of cyanobacterial blooms in different habitats of the reef systems off Old Providence Island, and identified the main bloom forming taxa. Cyanobacteria were registered in four different ecosystems, six geomorphological zones and nine habitats. Benthic cyanobacteria reached 18 to 72 % of the total cover in five habitats, particularly at the northwest, east and southeast portions of the island. These blooms consisted of complex consortia belonging to the genera Okeania, Lyngbya, Symploca, Phormidium, Oscillatoria or Spirulina. A bloom of planktonic cyanobacteria was dominated by Trichodesmium and developed on the fore reef of the island (NW), following heavy rains. These results suggest a potential new stressor for the island's reef complex. Future research should focus on the environmental factors that enable cyanobacterial blooms and their local impact on ecosystems and services.

show abstract

“…The study identified deuterostome's lineage as the most promising metazoan lineage for the discovery of bioactive agents. Phylogenetics have also been successfully used to determine the target clades of cyanobacteria that produce natural products [21]. A study that constructed genus-level phylogenetic tree representing 20,000 species from three biodiversity hotspots revealed that traditional medicinal plant use is not scattered randomly but is concentrated in certain parts of the phylogenetic trees [22].…”

mentioning

confidence: 99%

Phylogenetics: Tracing the Evolutionary Legacy of Organisms, Metastatic Clones, Bioactive Compounds and Languages

2015

J Phylogenetics Evol Biol

View full text Add to dashboard Cite

Since its inception seventy-five years ago, the field of phylogenetics has steadily been expanding to contribute in a number of scientific fields including biogeography, medicinal chemistry, forensics, transcriptomics, cancer biology and even linguistics, in addition to systematic biology -for which it was originally erupted by Willi Hennig. In this invited editorial contributed to the Journal of Phylogenetics and Evolutionary Biology a big picture of this ever evolving field is expounded. Application of phylogenetic inference in biosystematics, phylogeography, phylogenetic selection of target taxa in medicinal chemistry, cancer phylogenetics, and linguistic phylogeny are reviewed with a personal perspective summarizing contribution to this interdisciplinary field from my group. Parametric methods such as Maximum Likelihood and Bayesian Inference have dramatically improved for last one decade, yet empirical solutions to some of the most fundamental issues, including homoplasmy and lineage sorting, remains to be materialized. This oft-quoted statement, though primarily intended to enlighten our consciousness to live in this fleeting presence, indeed reverberate over three billion years old odyssey of the life on planet earth. Tracing those passing events to make sense of Darwin's "tree of life" is what comes in the realms of phylogenetics-an arena that combined the power of probabilistic statistics with evolutionary biology. As simple as it may seem, phylogenetic inference starts with one simple but profound premise: past informs the present.Originally conceived in 1950 by German entomologist Willi Hennig [1] who used this technique in systematic taxonomy, the scope of phylogenetics have ever since expanded tremendously to a number of applied scientific and even liberal arts disciplines including cancer biology, medicinal chemistry, linguistics, and forensics. For example, by phylogenetic reconstruction of HIV strains -that evolve with each new infection leaving certain relics of the past, a dentist in Florida was found guilty of deliberately infecting the virus to his patients [2]. Research from my own group have revealed in 2015 that sporadic episodes of the "blood rain" phenomenon, reported since time immemorial and even can be found in Homer's Iliad, was due to the spores of subareal green microalgae Trentepohlia annulata, and that the strain of this algae from South India and that from Central Europe had such a DNA sequence homology to have it introduced very recently [3]. Currently phylogenetics occupy the center stage of practical evolutionary biology for tracing the evolutionary legacy of varied subjects including the originally-intended biological species, and products of scientific ingenuity such as gene expression profiles of microarray data (transcriptomics), metastatic clones in cancer, bioactive compounds in medicinal chemistry and even languages in comparative and historical linguistics.The field of systematic taxonomy have greatly benefitted from phylogenetics such that a new field "phylog...

show abstract

Phylogenetic Inferences Reveal a Large Extent of Novel Biodiversity in Chemically Rich Tropical Marine Cyanobacteria

Cited by 67 publications

References 51 publications

Species concepts and speciation factors in cyanobacteria, with connection to the problems of diversity and classification

Species concepts and speciation factors in cyanobacteria, with connection to the problems of diversity and classification

Spatial scale of cyanobacterial blooms in Old Providence Island, Colombian Caribbean

Phylogenetics: Tracing the Evolutionary Legacy of Organisms, Metastatic Clones, Bioactive Compounds and Languages

Contact Info

Product

Resources

About