Your search keyword '"Goniopora lobata"' showing total 3 results

1. Reformation of tissue balls from tentacle explants of coral Goniopora lobata: self-organization process and response to environmental stresses.

Author

Lu, Qiongxuan, Liu, Tao, Tang, Xianming, Dong, Bo, and Guo, Huarong

Abstract

Coral has strong regeneration ability, which has been applied for coral production and biodiversity protection via tissue ball (TB) culture. However, the architecture, morphological processes, and effects of environmental factors on TB formation have not been well investigated. In this study, we first observed TB formation from the cutting tentacle of scleractinia coral Goniopora lobata and uncovered its inner organization and architecture by confocal microscopy. We then found that the cutting tentacle TB could self-organize and reform a solid TB (sTB) in the culture media. Using chemical drug treatment and dissection manipulation approaches, we demonstrated that the mechanical forces for bending and rounding of the cutting fragments came from the epithelial cells, and the cilia of epithelial cell played indispensable roles for the rounding process. Environmental stress experiments showed that high temperature, not CO-induced acidification, affected TB and sTB formation. However, the combination of high temperature and acidification caused additional severe effects on sTB reformation. Our studies indicate that coral TB has strong regeneration ability and therefore could serve as a new model to further explore the molecular mechanism of TB formation and the effects of environmental stresses on coral survival and regeneration. [ABSTRACT FROM AUTHOR]

Published

2017

2. The complete mitochondrial genome of the Goniopora lobata.

Author

Peng, Huipai, Zhang, Yanping, Shen, Cheng, and Liu, Li

Subjects

SCLERACTINIA, TRANSFER RNA, GENOMES, RIBOSOMAL RNA, NUCLEOTIDE sequencing

Abstract

In this study, the complete mitogenome sequence of the Goniopora lobata has been sequenced using next-generation sequence method. The overall of G. lobata mitogenome is 25.72% for A, 13.59% for C, 23.42% for G, and 37.27% for T, as well as 37.01% for low GC. The assembled mitogenome, consisting of 18770 bp, has 13 unique protein-coding genes (PCGs), three transfer RNA genes, and two ribosomal RNA genes. The complete mitogenome of G. lobata provides essential and important DNA molecular data for further phylogenetic and evolutionary analysis of stony coral phylogeny. [ABSTRACT FROM AUTHOR]

Published

2020

3. Diel ‘tuning’ of coral metabolism: physiological responses to light cues.

Author

Levy, O., Achituv, Y., Yacobi, Y. Z., Dubinsky, Z., and Stambler, N.

Subjects

CORALS, PHOTOSYNTHETIC oxygen evolution, ULTRAVIOLET radiation, PHYSIOLOGICAL effects of water temperature, CATALASE, REACTIVE oxygen species

Abstract

Hermatypic-zooxanthellate corals track the diel patterns of the main environmental parameters - temperature, UV and visible light - by acclimation processes that include biochemical responses. The diel course of solar radiation is followed by photosynthesis rates and thereby elicits simultaneous changes in tissue oxygen tension due to the shift in photosynthesis/respiration balance. The recurrent patterns of sunlight are reflected in fluorescence yields, photosynthetic pigment content and activity of the two protective enzymes superoxide dismutase (SOD) and catalase (CAT), enzymes that are among the universal defenses against free radical damage in living tissue. All of these were investigated in three scleractinian corals: Favia favus, Plerogyra sinuosa and Goniopora lobata. The activity of SOD and CAT in the animal host followed the course of solar radiation, increased with the rates of photosynthetic oxygen production and was correlated with a decrease in the maximum quantum yield of photochemistry in Photosystem II (PSII) (ΔF′/Fm′). SOD and CAT activity in the symbiotic algae also exhibited a light intensity correlated pattern, albeit a less pronounced one. The observed rise of the free-radical-scavenger enzymes, with a time scale of minutes to several hours, is an important protective mechanism for the existence and remarkable success of the unique cnidarian-dinoflagellate associations, in which photosynthetic oxygen production takes place within animal cells. This represents a facet of the precarious act of balancing the photosynthetic production of oxygen by the algal symbionts with their destructive action on all living cells, especially those of the animal host. [ABSTRACT FROM AUTHOR]

Published

2006