Your search keyword '"Haas, Andreas F."' showing total 59 results

51. Effects of Coral Reef Benthic Primary Producers on Dissolved Organic Carbon and Microbial Activity

Author

Haas, Andreas F., primary, Nelson, Craig E., additional, Wegley Kelly, Linda, additional, Carlson, Craig A., additional, Rohwer, Forest, additional, Leichter, James J., additional, Wyatt, Alex, additional, and Smith, Jennifer E., additional

Published

2011

52. Organic matter release by coral reef associated benthic algae in the Northern Red Sea

Author

Haas, Andreas F., primary, Naumann, Malik S., additional, Struck, Ulrich, additional, Mayr, Christoph, additional, el-Zibdah, Mohammad, additional, and Wild, Christian, additional

Published

2010

53. Organic matter release by Red Sea coral reef organisms — potential effects on microbial activity and in situ O2 availability.

Author

Wild, Christian, Niggl, Wolfgang, Naumann, Malik S., and Haas, Andreas F.

Subjects

ORGANIC compounds, REEF organisms, MICROBIOLOGY, OXYGEN, CORALS, JELLYFISHES, ALGAE, REEFS

Abstract

The article presents a study which examines the effects of organic matter (OM) released by reef organisms in Northern Red Sea to the microbial activity and to the oxygen concentration availability. The study uses four types of reef organisms which are the scleractinian and fire corals, the jellyfish, and the reef-associated algae. The study also uses the transect surveys of four seasonal expeditions, the collection of reef specimens at the Marine Science Station (MSS), and the quantification of OM released by the reef organisms. The study shows that OM from the algae which is the dissolved organic carbon (DOC) had stimulated the microbial activity, while the benthic reef algae had influence the decrease of oxygen availability due to the release of labile OM.

Published

2010

54. Organic matter release by the dominant primary producers in a Caribbean reef lagoon: implication for in situ O2 availability.

Author

Haas, Andreas F., Jantzen, Carin, Naumann, Malik S., Iglesias-Prieto, Roberto, and Wild, Christian

Subjects

DISSOLVED organic matter, DISSOLVED oxygen in water, BENTHIC plants, SEAGRASSES, ALGAE, CORAL reefs & islands, LAGOONS

Abstract

The article presents a study on the implication for in situ oxygen (O2) availability of the organic matters release by the dominant benthic primary producers in the coral reef lagoon of Puerto Morelos, Mexican Caribbean. The study looks into the quantity of particulates and dissolved organic matter (DOMs) released by the seagrasses, macroalgae, and scleractinian corals in the reef lagoon. It examines the microbial degradability of the released organic matters along with diurnal in situ O2 concentration measurements at lagoon sites dominated by different primary producers. The results reveal that the ecosystem functioning is affected by the shifts in benthic primary producer dominance due to differences in quantity, composition, and microbial degradability of the released organic matter.

Published

2010

55. Benthic community composition affects O2 availability and variability in a Northern Red Sea fringing reef.

Author

Niggl, Wolfgang, Haas, Andreas F., and Wild, Christian

Subjects

*CORAL reefs & islands, *GROUNDFISHES, *ALGAE, *REEF organisms, *CORALS

Abstract

Many coral reef ecosystems experience shifts in benthic community composition from scleractinian corals to algae. However, consequences of such phase shifts on O2 availability, important for many reef organisms, are unresolved. This study therefore comparatively investigated potential in situ effects of different benthic cover by reef macroalgae and scleractinian corals on water column O2 concentrations in a Northern Red Sea fringing reef. Findings revealed that mean daily O2 concentrations at algae-dominated sites were significantly lower compared to coral-dominated sites. Minimum O2 concentrations were significantly negatively correlated, while diurnal variability in O2 concentration was significantly positively correlated, with increasing benthic cover by algae. In contrast, no correlation with coral cover was found. These results indicate that shifts from corals to benthic algae may likely affect both in situ O2 availability and variability. This may be particularly pronounced in reef systems with low water exchange (e.g. closed lagoons) or under calm weather conditions and suggests potential O2-mediated effects on reef organisms. [ABSTRACT FROM AUTHOR]

Published

2010

56. Challenges in microbial ecology: building predictive understanding of community function and dynamics

Author

Widder, Stefanie, Allen, Rosalind J, Pfeiffer, Thomas, Curtis, Thomas P, Wiuf, Carsten, Sloan, William T, Cordero, Otto X, Brown, Sam P, Momeni, Babak, Shou, Wenying, Kettle, Helen, Flint, Harry J, Haas, Andreas F, Laroche, Béatrice, Kreft, Jan-Ulrich, Rainey, Paul B, Freilich, Shiri, Schuster, Stefan, Milferstedt, Kim, Van Der Meer, Jan R, Groβkopf, Tobias, Huisman, Jef, Free, Andrew, Picioreanu, Cristian, Quince, Christopher, Klapper, Isaac, Labarthe, Simon, Smets, Barth F, Wang, Harris, Fellows, Isaac Newton Institute, and Soyer, Orkun S

Subjects

13. Climate action, Air Microbiology, Animals, Humans, Seawater, 15. Life on land, Models, Theoretical, Ecosystem, Soil Microbiology

Abstract

The importance of microbial communities (MCs) cannot be overstated. MCs underpin the biogeochemical cycles of the earth's soil, oceans and the atmosphere, and perform ecosystem functions that impact plants, animals and humans. Yet our ability to predict and manage the function of these highly complex, dynamically changing communities is limited. Building predictive models that link MC composition to function is a key emerging challenge in microbial ecology. Here, we argue that addressing this challenge requires close coordination of experimental data collection and method development with mathematical model building. We discuss specific examples where model-experiment integration has already resulted in important insights into MC function and structure. We also highlight key research questions that still demand better integration of experiments and models. We argue that such integration is needed to achieve significant progress in our understanding of MC dynamics and function, and we make specific practical suggestions as to how this could be achieved.

57. Coral high molecular weight carbohydrates support opportunistic microbes in bacterioplankton from an algae-dominated reef.

Author

Thobor BM, Haas AF, Wild C, Nelson CE, Wegley Kelly L, Hehemann J-H, Arts MGI, Boer M, Buck-Wiese H, Nguyen NP, Hellige I, and Mueller B

Abstract

High molecular weight (HMW; >1 kDa) carbohydrates are a major component of dissolved organic matter (DOM) released by benthic primary producers. Despite shifts from coral to algae dominance on many reefs, little is known about the effects of exuded carbohydrates on bacterioplankton communities in reef waters. We compared the monosaccharide composition of HMW carbohydrates exuded by hard corals and brown macroalgae and investigated the response of the bacterioplankton community of an algae-dominated Caribbean reef to the respective HMW fractions. HMW coral exudates were compositionally distinct from the ambient, algae-dominated reef waters and similar to coral mucus (high in arabinose). They further selected for opportunistic bacterioplankton taxa commonly associated with coral stress (i.e., Rhodobacteraceae , Phycisphaeraceae , Vibrionaceae , and Flavobacteriales ) and significantly increased the predicted energy-, amino acid-, and carbohydrate-metabolism by 28%, 44%, and 111%, respectively. In contrast, HMW carbohydrates exuded by algae were similar to those in algae tissue extracts and reef water (high in fucose) and did not significantly alter the composition and predicted metabolism of the bacterioplankton community. These results confirm earlier findings of coral exudates supporting efficient trophic transfer, while algae exudates may have stimulated microbial respiration instead of biomass production, thereby supporting the microbialization of reefs. In contrast to previous studies, HMW coral and not algal exudates selected for opportunistic microbes, suggesting that a shift in the prevalent DOM composition and not the exudate type (i.e., coral vs algae) per se , may induce the rise of opportunistic microbial taxa., Importance: Dissolved organic matter (DOM) released by benthic primary producers fuels coral reef food webs. Anthropogenic stressors cause shifts from coral to algae dominance on many reefs, and resulting alterations in the DOM pool can promote opportunistic microbes and potential coral pathogens in reef water. To better understand these DOM-induced effects on bacterioplankton communities, we compared the carbohydrate composition of coral- and macroalgae-DOM and analyzed the response of bacterioplankton from an algae-dominated reef to these DOM types. In line with the proposed microbialization of reefs, coral-DOM was efficiently utilized, promoting energy transfer to higher trophic levels, whereas macroalgae-DOM likely stimulated microbial respiration over biomass production. Contrary to earlier findings, coral- and not algal-DOM selected for opportunistic microbial taxa, indicating that a change in the prevalent DOM composition, and not DOM type, may promote the rise of opportunistic microbes. Presented results may also apply to other coastal marine ecosystems undergoing benthic community shifts.

Published

2024

58. Coral larval settlement induction using tissue-associated and exuded coralline algae metabolites and the identification of putative chemical cues.

Author

Quinlan ZA, Bennett MJ, Arts MGI, Levenstein M, Flores D, Tholen HM, Tichy L, Juarez G, Haas AF, Chamberland VF, Latijnhouwers KRW, Vermeij MJA, Johnson AW, Marhaver KL, and Kelly LW

Subjects

Animals, Larva, Cues, Coral Reefs, Ecosystem, Anthozoa

Abstract

Reef-building crustose coralline algae (CCA) are known to facilitate the settlement and metamorphosis of scleractinian coral larvae. In recent decades, CCA coverage has fallen globally and degrading environmental conditions continue to reduce coral survivorship, spurring new restoration interventions to rebuild coral reef health. In this study, naturally produced chemical compounds (metabolites) were collected from two pantropical CCA genera to isolate and classify those that induce coral settlement. In experiments using four ecologically important Caribbean coral species, we demonstrate the applicability of extracted, CCA-derived metabolites to improve larval settlement success in coral breeding and restoration efforts. Tissue-associated CCA metabolites induced settlement of one coral species, Orbicella faveolata , while metabolites exuded by CCA (exometabolites) induced settlement of three species: Acropora palmata , Colpophyllia natans and Orbicella faveolata . In a follow-up experiment, CCA exometabolites fractionated and preserved using two different extraction resins induced the same level of larval settlement as the unfractionated positive control exometabolites. The fractionated CCA exometabolite pools were characterized using liquid chromatography tandem mass spectrometry, yielding 145 distinct molecular subnetworks that were statistically defined as CCA-derived and could be classified into 10 broad chemical classes. Identifying these compounds can reveal their natural prevalence in coral reef habitats and facilitate the development of new applications to enhance larval settlement and the survival of coral juveniles.

Published

2023

59. Brilliantia kiribatiensis, a new genus and species of Cladophorales (Chlorophyta) from the remote coral reefs of the Southern Line Islands, Pacific Ocean.

Author

Leliaert F, Kelly ELA, Janouškovec J, Fox MD, Johnson MD, Redfern FM, Eria T, Haas AF, Sala E, Sandin SA, and Smith JE

Subjects

DNA, Ribosomal, Pacific Ocean, Phylogeny, Chlorophyta, Coral Reefs

Abstract

The marine green alga Brilliantia kiribatiensis gen. et sp. nov. is described from samples collected from the coral reefs of the Southern Line Islands, Republic of Kiribati, Pacific Ocean. Phylogenetic analysis of sequences of the large- and small-subunit rDNA and the rDNA internal transcribed spacer region revealed that Brilliantia is a member of the Boodleaceae (Cladophorales), containing the genera Apjohnia, Boodlea, Cladophoropsis, Chamaedoris, Phyllodictyon, and Struvea. Within this clade it formed a distinct lineage, sister to Struvea elegans, but more distantly related to the bona fide Struvea species (including the type S. plumosa). Brilliantia differs from the other genera by having a very simple architecture forming upright, unbranched, single-celled filaments attached to the substratum by a rhizoidal mat. Cell division occurs by segregative cell division only at the onset of reproduction. Based on current sample collection, B. kiribatiensis seems to be largely restricted to the Southern Line Islands, although it was also observed on neighboring islands, including Orona Atoll in the Phoenix Islands of Kiribati, and the Rangiroa and Takapoto Atolls in the Tuamotus of French Polynesia. This discovery highlights the likeliness that there is still much biodiversity yet to be discovered from these remote and pristine reefs of the central Pacific., (© 2021 Phycological Society of America.)

Published

2022