Illuminated darkness: Molecular signatures of Congo River dissolved organic matter and its photochemical alteration as revealed by ultrahigh precision mass spectrometry

Stubbins, Aron; Spencer, Robert G. M.; Chen, Hongmei; Hatcher, Patrick G.; Mopper, Kenneth; Hernes, Peter J.; Mwamba, Vincent Lukanda; Mangangu, Arthur M.; Wabakanghanzi, José N.; Six, Johan

doi:10.4319/lo.2010.55.4.1467

Cited by 545 publications

(745 citation statements)

References 46 publications

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“…This finding is further ARTICLE substantiated by an independent photodegradation experiment on DOM in a tropical river system 13 . Direct comparison of compounds in our study with those from this independent photodegradation experiment 13 revealed that a striking 78% of compounds associated with lower levels of precipitation and 55% of compounds associated with longer WRT in our study were identified as photoresistant 13 ( Fig. 4b,d).…”

Section: Molecular Associations With Precipitation and Residence Timesupporting

confidence: 66%

“…4b,d). In addition, 64% of compounds associated with high precipitation and 77% of compounds associated with shorter WRT in our study were independently identified as photolabile 13 (Fig. 4a,c).…”

Section: Molecular Associations With Precipitation and Residence Timesupporting

confidence: 52%

“…The burgeoning use of mass spectrometry in DOM studies has tremendously advanced our molecular-level understanding of DOM dynamics [11][12][13][14][15] . Recent developments in data processing now enable us to analyze the detailed molecular composition of DOM as a function of environmental gradients over a large number of samples.…”

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confidence: 99%

“…As the chemical composition of DOM constrains its microbial degradation 17 , chemodiversity may be useful in setting a baseline for the degradation potential of a system. Compounds range from photoreactive molecules like combustion-derived polycyclic aromatics, vascular plant-derived polyphenols, and highly unsaturated and phenolic compounds, to photoresistant aliphatic compounds and peptides 13 . Photoreactive compounds are often thought to be biologically recalcitrant, with aliphatic compounds and peptides being more bioavailable; however, allochthonous carbon has also been shown to be an important substrate for bacterial growth 18 , and photochemical transformations can enhance the bacterial mineralization of previously recalcitrant DOM 19 .…”

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confidence: 99%

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Chemodiversity of dissolved organic matter in lakes driven by climate and hydrology

et al. 2014

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Despite the small continental coverage of lakes, they are hotspots of carbon cycling, largely due to the processing of terrestrially derived dissolved organic matter (DOM). As DOM is an amalgam of heterogeneous compounds comprising gradients of microbial and physicochemical reactivity, the factors influencing DOM processing at the molecular level and the resulting patterns in DOM composition are not well understood. Here we show, using ultrahigh-resolution mass spectrometry to unambiguously identify 4,032 molecular formulae in 120 lakes across Sweden, that the molecular composition of DOM is shaped by precipitation, water residence time and temperature. Terrestrially derived DOM is selectively lost as residence time increases, with warmer temperatures enhancing the production of nitrogen-containing compounds. Using biodiversity concepts, we show that the molecular diversity of DOM, or chemodiversity, increases with DOM and nutrient concentrations. The observed molecular-level patterns indicate that terrestrially derived DOM will become more prevalent in lakes as climate gets wetter.

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Section: Molecular Associations With Precipitation and Residence Timesupporting

confidence: 66%

Section: Molecular Associations With Precipitation and Residence Timesupporting

confidence: 52%

mentioning

confidence: 99%

mentioning

confidence: 99%

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Chemodiversity of dissolved organic matter in lakes driven by climate and hydrology

et al. 2014

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“…In accordance to their findings, we hypothesize that the DOM compounds and the total BC that reach the North Sea undergo mixing and transformation processes from the coast toward the Atlantic on similar timescales of several months and thus retain the intermediate history of the water masses, the 'riverine legacy'. Although taking place on similar timescales, processes influencing DOM and total BC composition are probably different: for example, the BC may respond to changes in temperature or nutrient supply (Fuhrman et al, 2008), whereas the DOM may be more affected by abiotic adsorption/desorption to surfaces (Gogou and Repeta, 2010), flocculation (Mikes et al, 2004) or photochemical processes (Stubbins et al, 2010).…”

Section: Identifying the Key Factors-bcmentioning

confidence: 99%

Deciphering associations between dissolved organic molecules and bacterial communities in a pelagic marine system

et al. 2016

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Dissolved organic matter (DOM) is the main substrate and energy source for heterotrophic bacterioplankton. To understand the interactions between DOM and the bacterial community (BC), it is important to identify the key factors on both sides in detail, chemically distinct moieties in DOM and the various bacterial taxa. Next-generation sequencing facilitates the classification of millions of reads of environmental DNA and RNA amplicons and ultrahigh-resolution mass spectrometry yields up to 10 000 DOM molecular formulae in a marine water sample. Linking this detailed biological and chemical information is a crucial first step toward a mechanistic understanding of the role of microorganisms in the marine carbon cycle. In this study, we interpreted the complex microbiological and molecular information via a novel combination of multivariate statistics. We were able to reveal distinct relationships between the key factors of organic matter cycling along a latitudinal transect across the North Sea. Total BC and DOM composition were mainly driven by mixing of distinct water masses and presumably retain their respective terrigenous imprint on similar timescales on their way through the North Sea. The active microbial community, however, was rather influenced by local events and correlated with specific DOM molecular formulae indicative of compounds that are easily degradable. These trends were most pronounced on the highest resolved level, that is, operationally defined 'species', reflecting the functional diversity of microorganisms at high taxonomic resolution.

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Pulsed, cross‐shelf export of terrigenous dissolved organic carbon to the Gulf of Mexico

2014

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The export of terrigenous dissolved organic carbon (tDOC) and other river-borne material across the continental shelf boundary has important ramifications for biological productivity and the cycling of continentally derived bioelements in the ocean. Recent studies revealed the 275-295 nm spectral slope coefficient of chromophoric dissolved organic matter (CDOM), S 275-295 , is a reliable tracer for terrigenous dissolved organic carbon (tDOC) in river-influenced ocean margins. Here an empirical algorithm for the accurate retrieval of S 275-295 from ocean color was developed and validated using in situ optical properties collected seasonally in the northern Gulf of Mexico. This study also demonstrated S 275-295 is a robust proxy for tDOC concentration in this environment, thereby providing a means to derive surface tDOC concentrations on synoptic scales and in quasi-real time using remote sensing. The resulting tDOC-algorithm was implemented using Aqua-MODIS in a retrospective analysis of surface tDOC concentrations over the northern Gulf of Mexico between July 2002 and June 2013. Large pulses of tDOC were observed in continentalslope surface waters off the Mississippi River delta, indicating cross-shelf export of tDOC was sporadic and exhibited considerable interannual variability. Favorable winds following an anomalously high discharge from the Mississippi-Atchafalaya river system always coincided with a major export event, and in general, cross-shelf export was enhanced during years of anomalously high discharge. The tDOC-algorithm will find applicability in the assessment of future climate-and human-induced changes in tDOC export, in biogeochemical models of the continental shelf, and in the validation of high-resolution coastal models of buoyancy-driven shelf circulation.

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Illuminated darkness: Molecular signatures of Congo River dissolved organic matter and its photochemical alteration as revealed by ultrahigh precision mass spectrometry

Cited by 545 publications

References 46 publications

Chemodiversity of dissolved organic matter in lakes driven by climate and hydrology

Chemodiversity of dissolved organic matter in lakes driven by climate and hydrology

Deciphering associations between dissolved organic molecules and bacterial communities in a pelagic marine system

Pulsed, cross‐shelf export of terrigenous dissolved organic carbon to the Gulf of Mexico

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