Babcock-Adams Lydia

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  • Thesis
    Molecular characterization of organically bound copper in the marine environment
    (Massachusetts Institute of Technology and Woods Hole Oceanographic Institution, 2022-05) Babcock-Adams, Lydia ; Repeta, Daniel J.
    Marine microbes require copper (Cu) for a variety of key enzymes and can therefore experience limitation when concentrations are low. However, when Cu concentrations are too high, it becomes toxic causing decreased cell growth and even cell death. Laboratory culture experiments have shown that a diverse array of microbes produce organic ligands that complex Cu (CuL) and buffer the free ion concentration, which is the most bioavailable fraction. In this way, the microbes impose a control on the speciation of Cu, decreasing the toxic effects of Cu and making seawater conditions favorable for growth. Studies have shown that CuL complexes produced in laboratory cultures have similar complexation strengths to those found in seawater samples, which suggests a biological source of CuLs in seawater where dissolved Cu is almost entirely bound by organic ligands. However, information about individual CuL complexes is lacking which limits our understanding of the sources, sinks, and cycling of dissolved Cu. In order to fill this gap in knowledge, molecular level information about CuL complexes produced in culture and found in seawater must be obtained. To investigate this, liquid chromatography (LC) was coupled to two mass spectrometers (MS), an inductively coupled plasma (ICP) MS and an electrospray ionization (ESI) MS. By using data supplied by both techniques, the molecular charateristics of CuLs were determined laboratory cultures of the marine diatom Phaeodactylum tricornutum and the cyanobacterium Synechococcus, as well as investigating the distribution of CuLs in natural seawater samples along a line from 56°N to 20°S, along 152°W through the north and central Pacific Ocean. The CuLs identified in laboratory cultures had molecular formulae and fragmentation patterns characteristic of linear tetrapyrroles, a group of organic compounds commonly found in biological systems. This identification was further supported by absorbance and nuclear magnetic resonance spectroscopy. The distribution of CuLs in the Pacific Ocean showed a highly dynamic and complex mixture of ligands, closely tied to biological cycles.
  • Article
    Element-selective targeting of nutrient metabolites in environmental samples by inductively coupled plasma mass spectrometry and electrospray ionization mass spectrometry
    (Frontiers Media, 2021-03-13) Li, Jingxuan ; Boiteau, Rene M. ; Babcock-Adams, Lydia ; Song, Zhongchang ; McIlvin, Matthew R. ; Repeta, Daniel J.
    Metabolites that incorporate elements other than carbon, nitrogen, hydrogen and oxygen can be selectively detected by inductively coupled mass spectrometry (ICPMS). When used in parallel with chromatographic separations and conventional electrospray ionization mass spectrometry (ESIMS), ICPMS allows the analyst to quickly find, characterize and identify target metabolites that carry nutrient elements (P, S, trace metals; “nutrient metabolites”), which are of particular interest to investigations of microbial biogeochemical cycles. This approach has been applied to the study of siderophores and other trace metal organic ligands in the ocean. The original method used mass search algorithms that relied on the ratio of stable isotopologues of iron, copper and nickel to assign mass spectra collected by ESIMS to metabolites carrying these elements detected by ICPMS. However, while isotopologue-based mass assignment algorithms were highly successful in characterizing metabolites that incorporate some trace metals, they do not realize the whole potential of the ICPMS/ESIMS approach as they cannot be used to assign the molecular ions of metabolites with monoisotopic elements or elements for which the ratio of stable isotopes is not known. Here we report a revised ICPMS/ESIMS method that incorporates a number of changes to the configuration of instrument hardware that improves sensitivity of the method by a factor of 4–5, and allows for more accurate quantitation of metabolites. We also describe a new suite of mass search algorithms that can find and characterize metabolites that carry monoisotopic elements. We used the new method to identify siderophores in a laboratory culture of Vibrio cyclitrophicus and a seawater sample collected in the North Pacific Ocean, and to assign molecular ions to monoisotopic cobalt and iodine nutrient metabolites in extracts of a laboratory culture of the marine cyanobacterium Prochorococcus MIT9215.
  • Article
    Iron depletion in the deep chlorophyll maximum: mesoscale eddies as natural iron fertilization experiments
    (American Geophysical Union, 2021-11-17) Hawco, Nicholas J. ; Barone, Benedetto ; Church, Matthew J. ; Babcock-Adams, Lydia ; Repeta, Daniel J. ; Wear, Emma K. ; Foreman, Rhea K. ; Björkman, Karin M. ; Bent, Shavonna M. ; Van Mooy, Benjamin A. S. ; Sheyn, Uri ; DeLong, Edward F. ; Acker, Marianne ; Kelly, Rachel L. ; Nelson, Alexa ; Ranieri, John ; Clemente, Tara M. ; Karl, David M. ; John, Seth G.
    In stratified oligotrophic waters, phytoplankton communities forming the deep chlorophyll maximum (DCM) are isolated from atmospheric iron sources above and remineralized iron sources below. Reduced supply leads to a minimum in dissolved iron (dFe) near 100 m, but it is unclear if iron limits growth at the DCM. Here, we propose that natural iron addition events occur regularly with the passage of mesoscale eddies, which alter the supply of dFe and other nutrients relative to the availability of light, and can be used to test for iron limitation at the DCM. This framework is applied to two eddies sampled in the North Pacific Subtropical Gyre. Observations in an anticyclonic eddy center indicated downwelling of iron-rich surface waters, leading to increased dFe at the DCM but no increase in productivity. In contrast, uplift of isopycnals within a cyclonic eddy center increased supply of both nitrate and dFe to the DCM, and led to dominance of picoeukaryotic phytoplankton. Iron addition experiments did not increase productivity in either eddy, but significant enhancement of leucine incorporation in the light was observed in the cyclonic eddy, a potential indicator of iron stress among Prochlorococcus. Rapid cycling of siderophores and low dFe:nitrate uptake ratios also indicate that a portion of the microbial community was stressed by low iron. However, near-complete nitrate drawdown in this eddy, which represents an extreme case in nutrient supply compared to nearby Hawaii Ocean Time-series observations, suggests that recycling of dFe in oligotrophic ecosystems is sufficient to avoid iron limitation in the DCM under typical conditions.
  • Article
    Insights into the physiological and genomic characterization of three bacterial isolates from a highly alkaline, terrestrial serpentinizing system
    (Frontiers Media, 2023-07-12) Thompson, Jaclyn ; Barr, Casey R. ; Babcock-Adams, Lydia ; Bird, Lina ; La Cava, Eugenio ; Garber, Arkadiy ; Hongoh, Yuichi ; Liu, Mark ; Nealson, Kenneth H. ; Okamoto, Akihiro ; Repeta, Daniel J. ; Suzuki, Shino ; Tacto, Clarissa ; Tashjian, Michelle ; Merino, Nancy
    The terrestrial serpentinite-hosted ecosystem known as “The Cedars” is home to a diverse microbial community persisting under highly alkaline (pH ~ 12) and reducing (Eh < −550 mV) conditions. This extreme environment presents particular difficulties for microbial life, and efforts to isolate microorganisms from The Cedars over the past decade have remained challenging. Herein, we report the initial physiological assessment and/or full genomic characterization of three isolates: Paenibacillus sp. Cedars (‘Paeni-Cedars’), Alishewanella sp. BS5-314 (‘Ali-BS5-314’), and Anaerobacillus sp. CMMVII (‘Anaero-CMMVII’). Paeni-Cedars is a Gram-positive, rod-shaped, mesophilic facultative anaerobe that grows between pH 7–10 (minimum pH tested was 7), temperatures 20–40°C, and 0–3% NaCl concentration. The addition of 10–20 mM CaCl2 enhanced growth, and iron reduction was observed in the following order, 2-line ferrihydrite > magnetite > serpentinite ~ chromite ~ hematite. Genome analysis identified genes for flavin-mediated iron reduction and synthesis of a bacillibactin-like, catechol-type siderophore. Ali-BS5-314 is a Gram-negative, rod-shaped, mesophilic, facultative anaerobic alkaliphile that grows between pH 10–12 and temperatures 10–40°C, with limited growth observed 1–5% NaCl. Nitrate is used as a terminal electron acceptor under anaerobic conditions, which was corroborated by genome analysis. The Ali-BS5-314 genome also includes genes for benzoate-like compound metabolism. Anaero-CMMVII remained difficult to cultivate for physiological studies; however, growth was observed between pH 9–12, with the addition of 0.01–1% yeast extract. Anaero-CMMVII is a probable oxygen-tolerant anaerobic alkaliphile with hydrogenotrophic respiration coupled with nitrate reduction, as determined by genome analysis. Based on single-copy genes, ANI, AAI and dDDH analyses, Paeni-Cedars and Ali-BS5-314 are related to other species (P. glucanolyticus and A. aestuarii, respectively), and Anaero-CMMVII represents a new species. The characterization of these three isolates demonstrate the range of ecophysiological adaptations and metabolisms present in serpentinite-hosted ecosystems, including mineral reduction, alkaliphily, and siderophore production.