Impact of the Deepwater Horizon oil spill on a deep-water coral community in the Gulf of Mexico

To assess the potential impact of the Deepwater Horizon oil spill on offshore ecosystems, 11 sites hosting deep-water coral communities were examined 3 to 4 mo after the well was capped. Healthy coral communities were observed at all sites >20 km from the Macondo well, including seven sites previously visited in September 2009, where the corals and communities appeared unchanged. However, at one site 11 km southwest of the Macondo well, coral colonies presented widespread signs of stress, including varying degrees of tissue loss, sclerite enlargement, excess mucous production, bleached commensal ophiuroids, and covering by brown flocculent material (floc). On the basis of these criteria the level of impact to individual colonies was ranked from 0 (least impact) to 4 (greatest impact). Of the 43 corals imaged at that site, 46% exhibited evidence of impact on more than half of the colony, whereas nearly a quarter of all of the corals showed impact to >90% of the colony. Additionally, 53% of these corals’ ophiuroid associates displayed abnormal color and/or attachment posture. Analysis of hopanoid petroleum biomarkers isolated from the floc provides strong evidence that this material contained oil from the Macondo well. The presence of recently damaged and deceased corals beneath the path of a previously documented plume emanating from the Macondo well provides compelling evidence that the oil impacted deep-water ecosystems. Our findings underscore the unprecedented nature of the spill in terms of its magnitude, release at depth, and impact to deep-water ecosystems.     

From the Cover: Applications of science and engineering to quantify and control the Deepwater Horizon oil spill

The unprecedented engagement of scientists from government, academia, and industry enabled multiple unanticipated and unique problems to be addressed during the Deepwater Horizon oil spill. During the months between the initial blowout on April 20, 2010, and the final well kill on September 19, 2010, researchers prepared options, analyses of tradeoffs, assessments, and calculations of uncertainties associated with the flow rate of the well, well shut in, killing the well, and determination of the location of oil released into the environment. This information was used in near real time by the National Incident Commander and other government decision-makers. It increased transparency into BP’s proposed actions and gave the government confidence that, at each stage proposed, courses of action had been thoroughly vetted to reduce risk to human life and the environment and improve chances of success.     

From the Cover: Osmotrophy in modular Ediacara organisms

The Ediacara biota include macroscopic, morphologically complex soft-bodied organisms that appear globally in the late Ediacaran Period (575–542 Ma). The physiology, feeding strategies, and functional morphology of the modular Ediacara organisms (rangeomorphs and erniettomorphs) remain debated but are critical for understanding their ecology and phylogeny. Their modular construction triggered numerous hypotheses concerning their likely feeding strategies, ranging from micro-to-macrophagus feeding to photoautotrophy to osmotrophy. Macrophagus feeding in rangeomorphs and erniettomorphs is inconsistent with their lack of oral openings, and photoautotrophy in rangeomorphs is contradicted by their habitats below the photic zone. Here, we combine theoretical models and empirical data to evaluate the feasibility of osmotrophy, which requires high surface area to volume (SA/V) ratios, as a primary feeding strategy of rangeomorphs and erniettomorphs. Although exclusively osmotrophic feeding in modern ecosystems is restricted to microscopic bacteria, this study suggests that (i) fractal branching of rangeomorph modules resulted in SA/V ratios comparable to those observed in modern osmotrophic bacteria, and (ii) rangeomorphs, and particularly erniettomorphs, could have achieved osmotrophic SA/V ratios similar to bacteria, provided their bodies included metabolically inert material. Thus, specific morphological adaptations observed in rangeomorphs and erniettomorphs may have represented strategies for overcoming physiological constraints that typically make osmotrophy prohibitive for macroscopic life forms. These results support the viability of osmotrophic feeding in rangeomorphs and erniettomorphs, help explain their taphonomic peculiarities, and point to the possible importance of earliest macroorganisms for cycling dissolved organic carbon that may have been present in abundance during Ediacaran times.     

From the Cover: Montsechia,an ancient aquatic angiosperm

The early diversification of angiosperms in diverse ecological niches is poorly understood. Some have proposed an origin in a darkened forest habitat and others an open aquatic or near aquatic habitat. The research presented here centers on Montsechia vidalii, first recovered from lithographic limestone deposits in the Pyrenees of Spain more than 100 y ago. This fossil material has been poorly understood and misinterpreted in the past. Now, based upon the study of more than 1,000 carefully prepared specimens, a detailed analysis of Montsechia is presented. The morphology and anatomy of the plant, including aspects of its reproduction, suggest that Montsechia is sister to Ceratophyllum (whenever cladistic analyses are made with or without a backbone). Montsechia was an aquatic angiosperm living and reproducing below the surface of the water, similar to Ceratophyllum. Montsechia is Barremian in age, raising questions about the very early divergence of the Ceratophyllum clade compared with its position as sister to eudicots in many cladistic analyses. Lower Cretaceous aquatic angiosperms, such as Archaefructus and Montsechia, open the possibility that aquatic plants were locally common at a very early stage of angiosperm evolution and that aquatic habitats may have played a major role in the diversification of some early angiosperm lineages.When did early angiosperms begin to diversify ecologically? This question is currently unanswered. Age estimates of the divergence of crown-group angiosperms using molecular clock data vary considerably, although it is in the range of (max. 210–) often accepted, 150–140 (min. 130) million years (1–7). Parsimony reconstruction of early angiosperm habit suggests that they may have been shrubs living in “damp, dark, and disturbed” habitats (8). In contrast, many living aquatic angiosperms are basal in angiosperm phylogenies [e.g., Nymphaeales in Amborella, Nymphaeales and Illiciales, Trimeniaceae-Austrobaileya (ANITA) or Ceratophyllales with the eudicots as commonly understood]. In the fossil record, we have found an aquatic angiosperm, Montsechia vidalii (Zeiller) Teixeira, which is an atypical plant fossil found in the Barremian (130–125 million years ago) freshwater limestone in the Pyrenees and Iberian Range in Spain. Montsechia (Fig. 1) lacks roots (no proximal or adventitious roots were found in more than 1,000 shoots examined) and shows flexible axes and two types of phyllotaxy and leaf morphology. The cuticle is very thin with rare stomata. The fruit is closed with a pore near the distal tip, indehiscent, and contains one unitegmic seed developed from an orthotropous and pendent ovule (Figs. 2 and ​and3).3). Cladistic analysis of these characters places Montsechia on the stem lineage basal to extant Ceratophyllum or a clade formed by Ceratophyllum and Chloranthaceae (Fig. 4) suggesting that mesangiosperms (non-ANITA angiosperms) existed 125 million years ago, as indicated by the tricolpate pollen record. Montsechia is well-adapted to a submerged aquatic habit. Montsechia is contemporaneous with another aquatic plant fossil, Archaefructus, indicating that some of the earliest angiosperms were fully aquatic very early in their ecological diversification.Open in a separate windowFig. 1.Long- and short-leaved forms of Montsechia vidalii. (A) The long-leaved specimen shows very flexuous branches and opposite, long leaves. LH02556. (Scale bar, 10 mm.) (B) The short-leaved specimen shows regularly developed lateral branches and tiny leaf rosettes. LH07198. (Scale bar, 10 mm.)Open in a separate windowFig. 2.Fruit and seed of Montsechia vidalii. The fruit shows a small apical pore (po). The funicle (f) of the single, upside-down seed (orthotropous pendent) is attached from the hilum (h) to the placenta (pl). (Scale bar, 500 µm.)Open in a separate windowFig. 3.Reconstructions of Montsechia vidalii. (A) The long-leaved form shows the opposite leaves and branches. (B) The short-leaved form shows the alternate phyllotaxy of leaves and branches bearing pairs of ascidiate, nonornamented fruits. (C and D) The fruit shows a small apical pore and a single seed developed from an orthotropous pendent ovule. The funicle arises from the placenta (near the micropyle) to the hilum (near the pollination pore). (C) Lateral view. (D) Front view. Diagram by O. Sanisidro, B.G., and V.D.-G.Open in a separate windowFig. 4.Most parsimonious position of Montsechia in a simplified tree derived from the matrix by Endress and Doyle (26) using the J & M backbone. Taxa in blue are considered ancestrally water-related (27). Diagram by C.C. and B.G.     

From the Cover: A DNA barcode for land plants

DNA barcoding involves sequencing a standard region of DNA as a tool for species identification. However, there has been no agreement on which region(s) should be used for barcoding land plants. To provide a community recommendation on a standard plant barcode, we have compared the performance of 7 leading candidate plastid DNA regions (atpF–atpH spacer, matK gene, rbcL gene, rpoB gene, rpoC1 gene, psbK–psbI spacer, and trnH–psbA spacer). Based on assessments of recoverability, sequence quality, and levels of species discrimination, we recommend the 2-locus combination of rbcL+matK as the plant barcode. This core 2-locus barcode will provide a universal framework for the routine use of DNA sequence data to identify specimens and contribute toward the discovery of overlooked species of land plants.     

From the Cover: Science in support of the Deepwater Horizon response

This introduction to the Special Feature presents the context for science during the Deepwater Horizon oil spill response, summarizes how scientific knowledge was integrated across disciplines and statutory responsibilities, identifies areas where scientific information was accurate and where it was not, and considers lessons learned and recommendations for future research and response. Scientific information was integrated within and across federal and state agencies, with input from nongovernmental scientists, across a diverse portfolio of needs—stopping the flow of oil, estimating the amount of oil, capturing and recovering the oil, tracking and forecasting surface oil, protecting coastal and oceanic wildlife and habitat, managing fisheries, and protecting the safety of seafood. Disciplines involved included atmospheric, oceanographic, biogeochemical, ecological, health, biological, and chemical sciences, physics, geology, and mechanical and chemical engineering. Platforms ranged from satellites and planes to ships, buoys, gliders, and remotely operated vehicles to laboratories and computer simulations. The unprecedented response effort depended directly on intense and extensive scientific and engineering data, information, and advice. Many valuable lessons were learned that should be applied to future events.     

From the Cover: PNAS Plus: Pan-neuronal imaging in roaming Caenorhabditis elegans

We present an imaging system for pan-neuronal recording in crawling Caenorhabditis elegans. A spinning disk confocal microscope, modified for automated tracking of the C. elegans head ganglia, simultaneously records the activity and position of ∼80 neurons that coexpress cytoplasmic calcium indicator GCaMP6s and nuclear localized red fluorescent protein at 10 volumes per second. We developed a behavioral analysis algorithm that maps the movements of the head ganglia to the animal’s posture and locomotion. Image registration and analysis software automatically assigns an index to each nucleus and calculates the corresponding calcium signal. Neurons with highly stereotyped positions can be associated with unique indexes and subsequently identified using an atlas of the worm nervous system. To test our system, we analyzed the brainwide activity patterns of moving worms subjected to thermosensory inputs. We demonstrate that our setup is able to uncover representations of sensory input and motor output of individual neurons from brainwide dynamics. Our imaging setup and analysis pipeline should facilitate mapping circuits for sensory to motor transformation in transparent behaving animals such as C. elegans and Drosophila larva.Understanding how brain dynamics creates behaviors requires quantifying the flow and transformation of sensory information to motor output in behaving animals. Optical imaging using genetically encoded calcium or voltage fluorescent probes offers a minimally invasive method to record neural activity in intact animals. The nematode Caenorhabditis elegans is particularly ideal for optical neurophysiology owing to its small size, optical transparency, compact nervous system, and ease of genetic manipulation. Imaging systems for tracking the activity of small numbers of neurons have been effective in determining their role during nematode locomotion and navigational behaviors like chemotaxis, thermotaxis, and the escape response (1–6). Recordings from large numbers of interconnected neurons are required to understand how neuronal ensembles carry out the systematic transformations of sensory input into motor patterns that build behavioral decisions.Several methods for fast 3D imaging of neural activity in a fixed imaging volume have been developed for different model organisms (7–14). High-speed light sheet microscopy, light field microscopy, multifocus microscopy, and two-photon structured illumination microscopy have proved effective for rapidly recording large numbers of neurons in immobilized, intact, transparent animals like larval zebrafish and nematodes (15–19). However, these methods are problematic when attempting to track many neurons within the bending and moving body of a behaving animal. Panneuronal recording in moving animals poses higher demands on spatial and temporal resolution. Furthermore, extracting neuronal signals from recordings in a behaving animal requires an effective analysis pipeline to segment image volumes into the activity patterns of discrete and identifiable neurons.Here, we use high-speed spinning disk confocal microscopy—modified for automated tracking using real-time image analysis and motion control software—to volumetrically image the head ganglia of behaving C. elegans adults at single-cell resolution. Our setup can simultaneously track ∼80 neurons with 0.45 × 0.45 × 2-μm resolution at 10 Hz. Activity was reported by the ultrasensitive calcium indicator GCaMP6s expressed throughout the cytosol under the control of the pan-neuronal rgef-1 promoter (a gift from D. Pilgrim, University of Alberta, Edmonton, Alberta, Canada) (20). To facilitate segmentation into individual identifiable neurons, nuclei were tracked using calcium-insensitive, nuclear-bound red fluorescent protein (RFP), TagRFP, under the control of another pan-neuronal rab-3 promoter (a gift from O. Hobert, Columbia University, New York) (21). We developed an image analysis pipeline that converts the gross movements of the head into the time-varying position and posture of the crawling worm, and converts fluorescence measurements into near simultaneous activity patterns of all imaged neurons.A similar approach to brainwide imaging in moving C. elegans using the same transgenic strain has recently been reported (22). Although both setups use customized spinning disk confocal microscopes, the strategies for tracking the moving neurons and analyzing behavioral and neural activity patterns are different. Nguyen et al. (22) use a low power objective to track the posture of the animal and a high power objective to locate and image the nerve ring. The advantage of our single objective setup is that it affords the flexibility, for example, to deliver thermosensory inputs using an opaque temperature controlled stage below the animal. The advantage of low-magnification imaging is that it provides a direct measurement of animal posture, which we must infer. These new technologies for pan-neuronal imaging in roaming animals now enables correlating brainwide dynamics to sensory inputs and motor outputs in transparent behaving animals like C. elegans and Drosophila larvae.     

From the Cover: Altered temporal response of malaria parasites determines differential sensitivity to artemisinin

Reports of emerging resistance to first-line artemisinin antimalarials make it critical to define resistance mechanisms and identify in vitro correlates of resistance. Here we combine unique in vitro experimental and analytical approaches to mimic in vivo drug exposure in an effort to provide insight into mechanisms of drug resistance. Tightly synchronized parasites exposed to short drug pulses exhibit large stage-dependent differences in their drug response that correlate with hemoglobin digestion throughout most of the asexual cycle. As a result, ring-stage parasites can exhibit >100-fold lower sensitivity to short drug pulses than trophozoites, although we identify a subpopulation of rings (2–4 h postinvasion) that exhibits hypersensitivity. We find that laboratory strains that show little differences in drug sensitivity in standard in vitro assays exhibit substantial (>95-fold) difference in sensitivity when exposed to short drug pulses. These stage- and strain-dependent differences in drug sensitivity reflect differential response lag times with rings exhibiting lag times of up to 4 h. A simple model that assumes that the parasite experiences a saturable effective drug dose describes the complex dependence of parasite viability on both drug concentration and exposure time and is used to demonstrate that small changes in the parasite’s drug response profile can dramatically alter the sensitivity to artemisinins. This work demonstrates that effective resistance can arise from the interplay between the short in vivo half-life of the drug and the stage-specific lag time and provides the framework for understanding the mechanisms of drug action and parasite resistance.     

From the Cover: Experimental replacement of an obligate insect symbiont

Symbiosis, the close association of unrelated organisms, has been pivotal in biological diversification. In the obligate symbioses found in many insect hosts, organisms that were once independent are permanently and intimately associated, resulting in expanded ecological capabilities. The primary model for this kind of symbiosis is the association between the bacterium Buchnera and the pea aphid (Acyrthosiphon pisum). A longstanding obstacle to efforts to illuminate genetic changes underlying obligate symbioses has been the inability to experimentally disrupt and reconstitute symbiont–host partnerships. Our experiments show that Buchnera can be experimentally transferred between aphid matrilines and, furthermore, that Buchnera replacement has a massive effect on host fitness. Using a recipient pea aphid matriline containing Buchnera that are heat sensitive because of an allele eliminating the heat shock response of a small chaperone, we reduced native Buchnera through heat exposure and introduced a genetically distinct Buchnera from another matriline, achieving complete replacement and stable inheritance. This transfer disrupted 100 million years (∼1 billion generations) of continuous maternal transmission of Buchnera in its host aphids. Furthermore, aphids with the Buchnera replacement enjoyed a dramatic increase in heat tolerance, directly demonstrating a strong effect of symbiont genotype on host ecology.Symbiosis has been key in the ecological and evolutionary diversification of eukaryotes (1, 2). In many invertebrates, bacterial symbionts have been maternally transmitted for millions of years and are required for the growth and reproduction of hosts (3). These symbionts approach organelles in their degree of genetic and physiological integration with hosts and in their extreme genomic reduction. A model for obligate symbiosis is that of the pea aphid (Acyrthosiphon pisum) and its nutrient-provisioning bacterial symbiont, Buchnera aphidicola. Buchnera features a tiny genome (4), restriction to a small number of specialized host cells (bacteriocytes), host-controlled transmission (5), and regulated exchange of molecules with hosts (6, 7). This tight integration creates challenges for studies that aim to elucidate how symbiont variation affects host fitness and ecology.The ability to transfer obligate symbionts between host matrilines could provide a tool for teasing apart the separate contributions of symbiotic partners. Facultative symbionts, such as those conferring defense against pathogens, have been transferred experimentally into novel host matrilines, where they are typically stably inherited, enabling direct measures of symbionts on hosts (8). The success of these transfers is presumably related to the fact that facultative symbionts possess their own machinery for invading host cells (9, 10) and typically persist in several locations in the insect body. In contrast, obligate symbionts such as Buchnera are packaged into specialized host cells during early development and do not survive in the hemocoel or in other cell types.Buchnera colonizes developing aphids before birth, through a specialized transmission process that has been studied in detail in A. pisum (5, 11). Aphids are parthenogenetic for much of their life cycle, during which embryos develop within maternal ovarioles. Bacteriocytes and ovarioles containing developing embryos are located near one another within the mother’s abdomen, and transmission occurs when Buchnera cells are exocytosed from a maternal bacteriocyte in the vicinity of a blastula-stage embryo (5). The Buchnera cells become extracellular within the hemocoel, and some are endocytosed by the posterior syncytial cytoplasm of the embryo in which they are later packaged into the embryonic bacteriocytes. Buchnera cells released into the hemocoel quickly deteriorate if they do not enter an embryo. The molecular underpinnings of the transfer process are unknown. This specialized transmission process presents a challenge for the experimental transfer of symbionts between hosts.We developed a strategy aimed at replacing resident Buchnera with genetically distinct Buchnera from a different host matriline (Fig. 1), using parthenogenetic (all-female) lines of aphids. We used heat tolerance as a selectable phenotype. A previous study showed that a single nucleotide deletion in the promoter of a small heat shock protein [inclusion body-associated protein A (IbpA)] of Buchnera results in a reduction in Buchnera numbers of >100-fold after exposure to 4 h of 35 °C heat (12). Buchnera lacking this mutation undergo only modest declines after heat exposure. Our strategy was to reduce the native Buchnera in recipient aphids using heat, and then to inject homogenate containing heat-tolerant Buchnera from another A. pisum matriline. Because transmission to embryos includes an extracellular stage in which Buchnera is free in the hemocoel, the injected Buchnera might colonize embryos in lieu of maternal Buchnera, which have been eliminated or depleted. After successful replacement of native Buchnera, we demonstrated a large effect on aphid ability to withstand heat exposure.Open in a separate windowFig. 1.Experimental approach for replacement of the native Buchnera symbionts within an A. pisum matriline. The recipient line (LSR1) contains a heat-sensitive Buchnera genotype, and the donor (5AY) contains a heat-tolerant Buchnera genotype. Native Buchnera are depleted by heat in the recipient line, and microinjection is used to flood the hemocoel with donor Buchnera. Most embryos are successfully colonized by the donor symbionts. In some cases, complete replacement occurs in the progeny of injected females. In other cases, progeny have a mixed Buchnera population, which can be shifted completely to the donor type through further heat exposure.     

From the Cover: Cooperation and individuality among man-eating lions

Cooperation is the cornerstone of lion social behavior. In a notorious case, a coalition of two adult male lions from Tsavo, southern Kenya, cooperatively killed dozens of railway workers in 1898. The “man-eaters of Tsavo” have since become the subject of numerous popular accounts, including three Hollywood films. Yet the full extent of the lions'' man-eating behavior is unknown; estimates range widely from 28 to 135 victims. Here we use stable isotope ratios to quantify increasing dietary specialization on novel prey during a time of food limitation. For one lion, the δ¹³C and δ¹⁵N values of bone collagen and hair keratin (which reflect dietary inputs over years and months, respectively) reveal isotopic changes that are consistent with a progressive dietary specialization on humans. These findings not only support the hypothesis that prey scarcity drives individual dietary specialization, but also demonstrate that sustained dietary individuality can exist within a cooperative framework. The intensity of human predation (up to 30% reliance during the final months of 1898) is also associated with severe craniodental infirmities, which may have further promoted the inclusion of unconventional prey under perturbed environmental conditions.     

From the Cover: Widespread metabolic potential for nitrite and nitrate assimilation among Prochlorococcus ecotypes

The marine cyanobacterium Prochlorococcus is the most abundant photosynthetic organism in oligotrophic regions of the oceans. The inability to assimilate nitrate is considered an important factor underlying the distribution of Prochlorococcus, and thought to explain, in part, low abundance of Prochlorococcus in coastal, temperate, and upwelling zones. Here, we describe the widespread occurrence of a genomic island containing nitrite and nitrate assimilation genes in uncultured Prochlorococcus cells from marine surface waters. These genes are characterized by low GC content, form a separate phylogenetic clade most closely related to marine Synechococcus, and are located in a different genomic region compared with an orthologous cluster found in marine Synechococcus strains. This sequence distinction suggests that these genes were not transferred recently from Synechococcus. We demonstrate that the nitrogen assimilation genes encode functional proteins and are expressed in the ocean. Also, we find that their relative occurrence is higher in the Caribbean Sea and Indian Ocean compared with the Sargasso Sea and Eastern Pacific Ocean, which may be related to the nitrogen availability in each region. Our data suggest that the ability to assimilate nitrite and nitrate is associated with microdiverse lineages within high- and low-light (LL) adapted Prochlorococcus ecotypes. It challenges 2 long-held assumptions that (i) Prochlorococcus cannot assimilate nitrate, and (ii) only LL adapted ecotypes can use nitrite. The potential for previously unrecognized productivity by Prochlorococcus in the presence of oxidized nitrogen species has implications for understanding the biogeography of Prochlorococcus and its role in the oceanic carbon and nitrogen cycles.     

From the Cover: Transmission potential of Rickettsia felis infection by Anopheles gambiae mosquitoes

A growing number of recent reports have implicated Rickettsia felis as a human pathogen, paralleling the increasing detection of R. felis in arthropod hosts across the globe, primarily in fleas. Here Anopheles gambiae mosquitoes, the primary malarial vectors in sub-Saharan Africa, were fed with either blood meal infected with R. felis or infected cellular media administered in membrane feeding systems. In addition, a group of mosquitoes was fed on R. felis-infected BALB/c mice. The acquisition and persistence of R. felis in mosquitoes was demonstrated by quantitative PCR detection of the bacteria up to day 15 postinfection. R. felis was detected in mosquito feces up to day 14. Furthermore, R. felis was visualized by immunofluorescence in salivary glands, in and around the gut, and in the ovaries, although no vertical transmission was observed. R. felis was also found in the cotton used for sucrose feeding after the mosquitoes were fed infected blood. Natural bites from R. felis-infected An. gambiae were able to cause transient rickettsemias in mice, indicating that this mosquito species has the potential to be a vector of R. felis infection. This is particularly important given the recent report of high prevalence of R. felis infection in patients with “fever of unknown origin” in malaria-endemic areas.In 2002, Rickettsia felis, an obligate intracellular bacterium that belongs to the spotted fever group of Rickettsia, was definitively described (1, 2). Over the past 2 decades, an increasing number of reports have implicated R. felis as a human pathogen, paralleling an increase in reports of the detection of R. felis in arthropod hosts throughout the world (1, 3).By 2011, more than 70 human cases of R. felis had been reported worldwide, including in Central and South America, Asia, northern Africa, and Europe (1). More cases have been published since then, including the first probable human cases in Australia (4). In sub-Saharan Africa, recent studies have challenged the importance of R. felis infection in patients with “fever of unknown origin,” with this bacterium detected in up to 15% of such patients (5–7). In 2011, a potential R. felis primary infection, called “yaaf,” was suspected in the case of an 8-mo-old girl in Senegal with polymorphous skin lesions similar to those seen in patients from Mexico (8). The epidemiologic and clinical picture of this emerging infection in Africa, including its potential vectors, is poorly understood, however.Various arthropods, but primarily fleas, have been associated with R. felis (1, 3). More specifically, the cat flea Ctenocephalides felis is the arthropod in which R. felis has been most frequently detected. To date, it is the sole confirmed biological vector of R. felis, with both horizontal and vertical transmission making this flea a potential reservoir for this bacterium (9–11). However, in some countries where R. felis appears to be highly prevalent, such as Senegal, neither cat fleas nor other arthropods have been implicated in its transmission (12).Mosquitoes are the most important vectors of infectious diseases in humans, with more than one-half of the global population at risk for exposure to mosquito-borne infections (13, 14). Anopheles gambiae is known to be the primary vector of malaria in Africa, whereas Aedes albopictus is a vector of dengue and chikungunya (15, 16). Interestingly, Ae. albopictus and An. gambiae mosquito cells support R. felis growth (1, 17). In 2012, Ae. albopictus from Gabon and An. gambiae molecular form S (the primary African malarial vector) from Ivory Coast tested positive for R. felis by species-specific real-time quantitative PCR (qPCR) (17, 18). More recently, several mosquito species from Senegal were found to harbor R. felis, including Ae. luteocephalus, An. arabiensis, An. ziemanni, An. pharoensis, An. funestus, and Mansonia uniformis (5). These data raise new issues with respect to the epidemiology of R. felis in Africa, including the degree of vector competence of mosquitoes. The objective of this work was to study the acquisition and transmission of R. felis by An. gambiae mosquitoes in an experimental model of infection.