Preferential Expression of a Bromoperoxidase in Sporophytes of a Red Alga, Pyropia yezoensis

Matsuda, Ryuya; Özgür, Rengin; Higashi, Yuya; Takechi, Katsuaki; Takano, Hiroyoshi; Takio, Susumu

doi:10.1007/s10126-014-9608-6

Cited by 8 publications

(4 citation statements)

References 56 publications

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“…Therefore, we first evaluated the expression of thallus- and conchocelis-specific genes in the conchosporangium by quantitative reverse-transcriptase PCR (qRT-PCR). Previous reports have shown that genes encoding the alginate lyase (PyAly) 25 , sodium pump (PyKPA2) 26 , and ammonium transporter (PyAMT1) 27 are thallus specific, whereas genes encoding the sodium pump (PyKPA1) 28 , bromoperoxidase (PyBPO) 29 , and urea transporter (PyDUR3.3) 30 are conchocelis specific. Thus, we compared the expression levels of these genes in the thallus, conchosporangium, and conchocelis by qRT-PCR with gene-specific primers (Supplementary Table 1).…”

Section: Resultsmentioning

confidence: 99%

A unique life cycle transition in the red seaweed Pyropia yezoensis depends on apospory

Mikami

Irie

et al. 2019

Commun Biol

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Plant life cycles consist of two temporally separated stages: a haploid gametophyte and a diploid sporophyte. In plants employing a haploid–diploid sexual life cycle, the transition from sporophyte to gametophyte generally depends on meiosis. However, previous work has shown that in the red seaweed Pyropia yezoensis , this transition is independent of meiosis, though how and when it occurs is unknown. Here, we explored this question using transcriptomic profiling of P . yezoensis gametophytes, sporophytes, and conchosporangia parasitically produced on sporophytes. We identify a knotted-like homeobox gene that is predominately expressed in the conchosporangium and may determine its identity. We also find that spore-like single cells isolated from the conchosporangium develop directly into gametophytes, indicating that the gametophyte identity is established before the release of conchospores and prior to the onset of meiosis. Based on our findings, we propose a triphasic life cycle for P . yezoensis involving production of gametophytes by apospory.

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Section: Resultsmentioning

confidence: 99%

A unique life cycle transition in the red seaweed Pyropia yezoensis depends on apospory

Mikami

Irie

et al. 2019

Commun Biol

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“…A differential expression of haloperoxidases, which could then lead to the differential production of halogenated molecules, could explain the observed differences in the abundance of not only compound 4 but also other halogenated compounds. The preferential expression of a gene encoding for bromoperoxidase was already reported in the sporophyte stage of the red algae Pyropia yezoensis [ 33 ]. The authors showed that it was actively expressed in filamentous sporophytes, leading to bromoform production, but repressed in leafy gametophytes under normal growth conditions, which is in accordance with our hypothesis.…”

Section: Discussionmentioning

confidence: 94%

Antibacterial Activities and Life Cycle Stages of Asparagopsis armata: Implications of the Metabolome and Microbiome

Parchemin,

Raviglione,

Mejait

et al. 2023

Marine Drugs

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The red alga Asparagopsis armata is a species with a haplodiplophasic life cycle alternating between morphologically distinct stages. The species is known for its various biological activities linked to the production of halogenated compounds, which are described as having several roles for the algae such as the control of epiphytic bacterial communities. Several studies have reported differences in targeted halogenated compounds (using gas chromatography–mass spectrometry analysis (GC-MS)) and antibacterial activities between the tetrasporophyte and the gametophyte stages. To enlarge this picture, we analysed the metabolome (using liquid chromatography–mass spectrometry (LC-MS)), the antibacterial activity and the bacterial communities associated with several stages of the life cycle of A. armata: gametophytes, tetrasporophytes and female gametophytes with developed cystocarps. Our results revealed that the relative abundance of several halogenated molecules including dibromoacetic acid and some more halogenated molecules fluctuated depending on the different stages of the algae. The antibacterial activity of the tetrasporophyte extract was significantly higher than that of the extracts of the other two stages. Several highly halogenated compounds, which discriminate algal stages, were identified as candidate molecules responsible for the observed variation in antibacterial activity. The tetrasporophyte also harboured a significantly higher specific bacterial diversity, which is associated with a different bacterial community composition than the other two stages. This study provides elements that could help in understanding the processes that take place throughout the life cycle of A. armata with different potential energy investments between the development of reproductive elements, the production of halogenated molecules and the dynamics of bacterial communities.

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“…Our results showed that a homologue of haloperoxidase was significantly up-regulated in all infection experiments. Quantitative PCR analysis on a boromoperoxidase isolated from Pyropia yezoensis showed that it is actively expressed in filamentous sporophytes but repressed in leafy gametophytes under normal growth conditions (Matsuda et al 2015). Further studies on isolated halogenated compounds are necessary to understand their role in Pyropia defense against pathogens.…”

Section: Discussionmentioning

confidence: 99%

Genetic toolkits of the red alga Pyropia tenera against the three most common diseases in Pyropia farms

Klochkova

Lee

et al. 2019

Journal of Phycology

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Disease outbreaks devastate Pyropia aquaculture farms every year. The three most common and serious diseases are Olpidiopsis‐blight and red‐rot disease caused by oomycete pathogens and green‐spot disease caused by the PyroV1 virus. We hypothesized that a basic genetic profile of molecular defenses will be revealed by comparing and analyzing the genetic response of Pyropia tenera against the above three pathogens. RNAs isolated from infected thalli were hybridized onto an oligochip containing 15,115 primers designed from P. tenera expressed sequence tags (EST)s. Microarray profiles of the three diseases were compared and interpreted together with histochemical observation. Massive amounts of reactive oxygen species accumulated in P. tenera cells exposed to oomycete pathogens. Heat shock genes and serine proteases were the most highly up‐regulated genes in all infection experiments. Genes involved in RNA metabolism, ribosomal proteins and antioxidant metabolism were also highly up‐regulated. Genetic profiles of P. tenera in response to pathogens were most similar between the two biotrophic pathogens, Olpidiopsis pyropiae and PyroV1 virus. A group of plant resistance genes were specifically regulated against each pathogen. Our results suggested that disease response in P. tenera consists of a general constitutive defense and a genetic toolkit against specific pathogens.

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Preferential Expression of a Bromoperoxidase in Sporophytes of a Red Alga, Pyropia yezoensis

Cited by 8 publications

References 56 publications

A unique life cycle transition in the red seaweed Pyropia yezoensis depends on apospory

A unique life cycle transition in the red seaweed Pyropia yezoensis depends on apospory

Antibacterial Activities and Life Cycle Stages of Asparagopsis armata: Implications of the Metabolome and Microbiome

Genetic toolkits of the red alga Pyropia tenera against the three most common diseases in Pyropia farms

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