Impact of elevated CO2 concentrations on the growth and ultrastructure of non-calcifying marine diatom (Chaetoceros gracilis F.Schütt)

Khairy, Hanan M.; Shaltout, Nayrah A.; El-Naggar, Mona F; El-Naggar, Naglaa A.

doi:10.1016/j.ejar.2014.08.002

Cited by 13 publications

(10 citation statements)

References 38 publications

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“…The effect of CO 2 on the growth of diatoms is quite complex and, probably, depends on the particular physiology of each species. It has been shown that species can use different carbon sources, with some utilizing CO 2 as main carbon source, whereas others mostly drawing carbon from HCO 3 - [35]. Elevated CO 2 concentration did not cause significant differences in growth in diatoms such as Asterionella glacialis , Thalassiosira punctigera , Coscinodiscus wailesii , Phaeodactylum tricornutum [36–38].…”

Section: Discussionmentioning

confidence: 99%

“…Elevated CO 2 concentration did not cause significant differences in growth in diatoms such as Asterionella glacialis , Thalassiosira punctigera , Coscinodiscus wailesii , Phaeodactylum tricornutum [36–38]. In the case of Chaetoceros gracilis , the maximum number of cells was obtained at a carbon dioxide concentration of 385 μatm and a lower cell number was obtained at lower (control and 280 μatm) and higher levels of carbon dioxide (1,050 μatm) [35]. In other species, such as Thalassiosira weissflogii , algal density decreased with the decreasing pH [39] probably because, when the acidity is lower than a certain concentration, it will impair algal physiological functioning [40].…”

Section: Discussionmentioning

confidence: 99%

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Ocean acidification influences plant-animal interactions: The effect of Cocconeis scutellum parva on the sex reversal of Hippolyte inermis

Mutalipassi¹,

Mazzella²,

Zupo³

2019

PLoS ONE

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Ocean acidification (O.A.) influences the ecology of oceans and it may impact plant-animal interactions at various levels. Seagrass meadows located at acidified vents in the Bay of Naples (Italy) are considered an open window to forecast the effects of global-changes on aquatic communities. Epiphytic diatoms of the genus Cocconeis are abundant in seagrass meadows, including acidified environments, where they play key ecological roles. A still-unknown apoptogenic compound produced by Cocconeis triggers the suicide of the androgenic gland of Hippolyte inermis Leach 1816, a protandric hermaphroditic shrimp distributed in P . oceanica meadows located both at normal pH and in acidified vents. Feeding on Cocconeis sp . was proven important for the stability of the shrimp’s natural populations. Since O.A. affects the physiology of diatoms, we investigated if, in future scenarios of O.A., Cocconeis scutellum parva will still produce an effect on shrimp’s physiology. Cell densities of Cocconeis scutellum parva cultivated in custom-designed photobioreactors at two pH conditions (pH 7.7 and 8.2) were compared. In addition, we determined the effects of the ingestion of diatoms on the process of sex reversal of H . inermis and we calculated the % female on the total of mature individuals -1 (F/mat). We observed significant differences in cell densities of C . scutellum parva at the two pH conditions . In fact, the highest cell densities (148,808 ±13,935 cells. mm -2 ) was obtained at day 13 (pH 7.7) and it is higher than the highest cell densities (38,066 (±4,166) cells. mm -2 , day 13) produced at pH 8.2. Diatoms cultured at acidified conditions changed their metabolism. In fact, diatoms grown in acidified conditions produced in H . inermis a proportion of females (F/mat 36.3 ±5.9%) significantly lower than diatoms produced at normal pH (68.5 ±2.8), and it was not significantly different from that elicited by negative controls (31.7 ±5.6%).

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Ocean acidification influences plant-animal interactions: The effect of Cocconeis scutellum parva on the sex reversal of Hippolyte inermis

Mutalipassi¹,

Mazzella²,

Zupo³

2019

PLoS ONE

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“…Typically, low CO 2 level is insufficient for microalgal growth, whereas high CO 2 level often exerts detrimental effect (35; 36; 37). Chloroplast damage and organelles disorder which in turn render cell lysis were observed in high CO 2 level (38). Many microalgae have evolved CO 2 concentrating mechanism (CCM) to enhance the efficiency of photosynthetic carbon fixation by raising the CO 2 level around carboxylating enzyme ribulose bisphosphate carboxylase/oxygenase (RuBisCO) which responsible for the first step of carbon dioxide fixation ( Figure 2).…”

Section: Carbonmentioning

confidence: 99%

Macronutrient effect on biomass of Microalgae in biofuel production: A review

lowast¹,

Tan²,

Wong³

2020

IJST

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Objectives: This review is focused on the effect of macronutrients (nitrogen, carbon and phosphorus) on biomass production of microalgae especially concerned with biofuel. Methodology: The keyword search included "microalgae cultivation", "nitrogen sources", "phosphorus sources", "organic carbon", "biodiesel", "biofuel", "carbon dioxide", "inorganic carbon", "macronutrient deprivation", "macronutrient limitation", "lipid" and "organic waste" to search the published journals in ScienceDirect, Scopus, Springer, and Google Scholar. The search was performed from December 2019 until Mac 2020 to collect all the journals and books that are published between 2006 and 2020. The effect of each macronutrient (nitrogen, carbon and phosphorus) on microalgal growth of the control and the samples were compared using biomass productivity, concentration and biochemical content in each published article. Findings: Review shows that nitrogen has more pernicious effect than other macronutrients on most microalgal growth and lipid production. The concentrations and types of macronutrients have remarkable effects on the growth of microalgae; hence these criteria must be chosen scrupulously to achieve the desired biomass and metabolite production. In order to improve the biomass and biochemical productivity in concomitant with the cost reduction, replacement of cheap organic waste, genetic engineering of microalgae and two-stage hybrid system have been suggested to simultaneously maximize the biomass and biochemical production. The future research should focus on other biochemical contents such as carbohydrates, proteins and pigment to achieve the biorefinery context which can increase the profit. Besides, economic factor such as factorial design should be included in the future research to obtain the best combined factors with the maximum profit and minimal cost.

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“…Hal tersebut terjadi karena pada konsentrasi 385 ppm CO 2 makroalga masih dapat melakukan proses fisiologi dengan baik karena kebutuhan akan kalsium karbonat masih normal, ketika terjadi kenaikan konsentrasi CO 2 maka terjadi disolusi karbonat yang berpengaruh terhadap lapisan utricle dalam thallus sehingga mengganggu proses fotosintesa dan respirasi apalagi dengan terjadinya peningkatan suhu maka kebutuhan komponen dan proses metabolik semakin bertambah sehingga kemampuan kloroplas dalam dinding sel semakin menurun pula (Dijoux et al, 2012). Hasil penelitian Khairy et al (2014) juga terjadi pada fitoplankton Chaetoceros gracilis mengalami kerusakan kloroplas, disintegrasi membran tilakoid, dan terjadinya sel lyses ketika terjadi peningkatan konsentrasi CO 2 550-1.050 ppm.…”

Section: Kandungan Klorofil-aunclassified

“…Selanjutnya penjelasan Barry (2011) bahwa konsekuensi dari tingginya konsentrasi CO 2 adalah menurunnya aktifitas enzim, terjadi inefisiensi fungsi seluler (seperti sintesa protein), terjadi depresi metabolik, bahkan pada organisme fitoplankton berpengaruh terhadap produksi pigmen sel 689 dan produktifitasnya. Selanjutnya hasil penelitian Khairy et al (2014) bahwa kandungan total protein, karbohidrat dan lipid pada fitoplankton Chaetoceros gracilis menurun pada konsentrasi 550-1.050 ppm CO 2 . Sejalan dengan penemuan Porzio et al (2013) bahwa ganggang laut menunjukkan respon yang berbeda terhadap pengasaman laut, yang mana pada penurunan pH tidak selalu mendukung organisme fotosintetik laut.…”

Section: Pembahasanunclassified

INCREASING CARBON DIOXIDE CONCENTRATION AND TEMPERATURE ON GROWTH AND HISTOPATHOLOGY OF TROPIC MACROALGAE Halimeda sp

Sahabuddin

Jompa

Rukminasari

2016

J. Ilmu dan Teknologi Kelautan Tropis

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The increasing CO2 concentration and temperature affected growth, chlorophyll content, calcium content, and histological tissue of tropical macroalgae Halimeda sp. The study was conducted to examine the interaction effect of the increased CO2 concentration and temperature on growth, chlorophyll-a content, calcium content, and histological tissue of tropical macroalgae Halimeda sp in a laboratory. Research was set with a completely randomized factorial design at 3 levels of factors (A) the CO2 concentration: 385 ppm (ambient), 750 ppm (medium), 1000 ppm (high), and 3 levels of factor (B) the temperature: 30oC, 32oC, 34oC. Microcolony of macroalgae Halimeda sp were selected and obtained from the Lae-lae island then growing in the aquarium 30 x 30 x 45 cm3. Biological parameters observed were growth rate (total, specific and relative), chlorophyll-a content, calcium content, and histopathology tissue. The results showed that the increased of CO2 concentration and temperature negatively affected on the growth of Halimeda sp, reduced of the growth rate, the chlorophyll-a content, calcium content and damaged to histopatology tissue of the Halimeda sp at trophical macroalgae. Keywords: CO2 concentration, temperature, growth response, histopathology, Halimeda sp

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Impact of elevated CO2 concentrations on the growth and ultrastructure of non-calcifying marine diatom (Chaetoceros gracilis F.Schütt)

Cited by 13 publications

References 38 publications

Ocean acidification influences plant-animal interactions: The effect of Cocconeis scutellum parva on the sex reversal of Hippolyte inermis

Ocean acidification influences plant-animal interactions: The effect of Cocconeis scutellum parva on the sex reversal of Hippolyte inermis

Macronutrient effect on biomass of Microalgae in biofuel production: A review

INCREASING CARBON DIOXIDE CONCENTRATION AND TEMPERATURE ON GROWTH AND HISTOPATHOLOGY OF TROPIC MACROALGAE Halimeda sp

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