Your search keyword '"Noelia N. Barriga-Medina"' showing total 8 results

1. Microclimate is a strong predictor of the native and invasive plant‐associated soil microbiome on San Cristóbal Island, Galápagos archipelago

Author

Alexi A. Schoenborn, Sarah M. Yannarell, Caroline T. MacVicar, Noelia N. Barriga‐Medina, Kevin S. Bonham, Antonio Leon‐Reyes, Diego Riveros‐Iregui, Vanja Klepac‐Ceraj, and Elizabeth A. Shank

Subjects

Microbiology, Ecology, Evolution, Behavior and Systematics

Published

2023

2. Microclimate is a strong predictor of the native and invasive plant-associated soil microbiota on San Cristóbal Island, Galápagos archipelago

Author

Alexi A. Schoenborn, Sarah M. Yannarell, Caroline T. MacVicar, Noelia N. Barriga-Medina, Meng Markillie, Hugh Mitchell, Kevin S. Bonham, Antonio Leon-Reyes, Diego Riveros-Iregui, Vanja Klepac-Ceraj, and Elizabeth A. Shank

Abstract

Understanding the major drivers that influence soil bacterial and fungal communities is essential to mitigate the impacts of human activity on vulnerable ecosystems, like those found on the Galápagos Islands. Located ~1000 km off the coast of Ecuador, the volcanically formed islands are situated within distinct oceanic currents, which provide seasonal weather patterns and unique microclimates within small spatial scales across the islands. Although much is known about the impacts of human activity, such as climate change and invasive plant species, on above ground biodiversity of the Galápagos Islands, little is known about the resident soil microbial communities and the drivers that shape these communities. Here, our goal was to investigate the bacterial and fungal communities found in soil located in three distinct microclimates: Mirador (arid), Cerro Alto (transition zone), and El Junco (humid), and associated with native and invasive plant types. At each site, we collected soil at three depths (rhizosphere, 5 cm, and 15 cm) associated with the invasive plant, Psidium guajava (guava), and native plant types. We determined that the sampling location (microclimate) was the strongest driver of both bacterial and fungal communities (74 and 38%, respectively), with additional minor but significant impacts from plant type and soil depth. This study highlights the continued need to explore microbial communities across diverse environments and demonstrates the weight of different abiotic and biotic factors impacting soil microbial communities across San Cristóbal Island in the Galápagos archipelago.IMPORTANCE/SIGNIFICANCEHuman activity such as climate change, pollution, introduction of invasive species, and deforestation, poses a huge threat to biodiverse environments. Soil microbiota are an essential component to maintaining healthy ecosystems. However, a greater understanding of factors that alter these microbial communities is needed in order to find ways to mitigate and reverse the impacts imposed by human activity. The Galápagos Islands are a unique real-world laboratory, in that the islands’ biogeography and physical locations in the Pacific Ocean provide distinct microclimates within small geographic distances. Harnessing these distinct environments allowed us to investigate the influence of microclimates, soil depth, and vegetation cover on bacterial and fungal community composition.

Published

2022

3. First report of Pectobacterium peruviense as the causal pathogen of blackleg and soft rot in Solanum tuberosum cv. Superchola in Cañar, Ecuador.

Author

Peña-Zuñiga E, Barriga-Medina N, Ramirez-Villacis D, Miranda-Guerrero M, Pieterse C, Raaijmakers JM, and Leon-Reyes A

Abstract

Potato (Solanum tuberosum) is grown in Ecuador's Andean region at altitudes from 2,200 to 3,600 m.a.s.l., and the most commercially significant cultivar is Superchola, which constitutes 60% of total production, covering around 11,000 hectares (MAG, s.f. 2022). From November 2022 to January 2023, dark, water-soaked lesions progressing upwards from the base of the stems were observed on Superchola potato plants in Cañar, Ecuador (2°23'56.4''S 78°59'13.2''W). Approximately 20 plants in a hectare showed symptoms. Symptomatic stems from five plants were collected, surface-disinfected with 2% sodium hypochlorite, followed by 70% ethanol, and thoroughly rinsed with sterile distilled water. Plant tissue sections (1 cm²) were homogenized in 10 mM MgCl₂, serially diluted, and plated on Tryptic Soy Agar (TSA). After 48 hours of incubation at 28°C, creamy-white, yellowish, and white round colonies appeared. Streak plating was performed, yielding 14 purified bacterial isolates named M1 to M14. For the pathogenicity tests, each purified isolate was inoculated into healthy potato tubers and stem pieces (5 cm) using the prick inoculation method described by Ma et al. (2018) with modifications. Surface-sterilized tubers and stems were wounded using autoclaved toothpicks, into which 5µl of a bacterial suspension, carrying ~1 x 106 CFU/ml of bacteria per strain, was deposited into a 5 mm deep wound. Three independent replicates were conducted. Only one isolate, designated as M3, presented maceration on potato tubers, and dark, watered-soaked lesions appeared on the stem 48 h post-inoculation with strain. Other bacterial isolates showed no symptoms in either stems or tubers. Pathogenicity tests were confirmed on healthy, 4-week-old potato plants grown in a 50% perlite and 50% peat moss substrate. Inoculations were done using two methods: (1) toothpick piercing, where 5 µl of saline solution containing ~1 x 106 CFU/ml of bacteria was applied to a wound approximately 5mm deep (Ma et al. 2018), and (2) immersion of the plant foliage in a bacterial suspension of 1x 108 CFU/ml in saline solution for 10 min Controls used bacteria-free toothpicks (wounded) and sterile 10 mM MgCl₂ solution (unwounded). Plants were enclosed in plastic containers to maintain high humidity and grown at 15/25°C (day/night) with a 12 h photoperiod. Five days post-inoculation, blackleg symptoms were observed in the stems of the infected area, which turned black and rotten (wounded and unwounded). In all cases, negative controls remained symptomless. To complete Koch's postulates, bacteria were reisolated from symptomatic potato stems and showed the same morphology. To identify the isolate M3, whole genome sequencing using Oxford Nanopore technology was performed. Three marker genes were extracted, and a 5,734-bp sequence was concatenated from dnaX (2073 bp), recA (1,074bp), and leuS (2,583bp) (GenBank accession nos. PQ177849, PQ177847 and PQ177848, respectively). The concatenated sequences of M3 and type strains were used to construct a multilocus Bayesian inference phylogenetic tree using BEAST version 1.8.4. Isolate M3 grouped with Pectobacterium peruviense, showing a 100% sequence identity with the type strain P. peruviense IFB5232(Drummond et al. 2012; Portier et al. 2019; Toth et al. 2021; Waleron et al. 2018). To our knowledge, this is the first report of P. peruviense causing blackleg and soft rot in potato plants in Ecuador. Further research is essential, but this information could assist in monitoring the pathogen's spread and developing disease management strategies.

Published

2024

4. First Report of Lasiodiplodia theobromae Causing Fruit Crown Rot on Banana in Ecuador.

Author

Jaramillo-Aguilar E, Peña-Zuñiga E, Barriga-Medina N, Rodríguez-González D, Calderon LLM, Garces-Fiallos F, and Leon-Reyes A

Abstract

Post-harvest diseases like fruit crown rot (CR) on bananas (Musa spp.) worldwide are mainly attributed to Colletotrichum gloeosporioides (Berk. & Curt.) von Arx and Lasiodiplodia theobromae (Pat.) Griff. & Maubl (Sangeetha et al., 2012; Riera et al., 2019). In April 2019, at a banana farm (cultivar Williams) located in El Oro province (location at 79° 54' 05" W; 03° 17' 16" S), thirty hands were randomly collected from the postharvest process and further placed in a humid chamber at 20 ºC until signs of the disease progressed and became more evident (from 3 days to 20 days). Ten hands presented initial symptoms related to CR during the postharvest process, which included crown or peduncle rot with mycelial development on the crown's surface, leading to the blackening of tissues at the site of the wound left when the cluster was cut. Crown fruit fragments (~0.5 cm) from the edge of healthy tissue and diseased tissue underwent a series of disinfection steps, initially in ethanol (70%) for 1 min, followed by sodium hypochlorite (1%) for 1 min, rinsed three times with sterile distilled water, and dried on sterile filter paper for 10 min. The fragments were placed onto Potato dextrose agar (PDA) + chloramphenicol (100 mg L-1) and incubated at 25°C in darkness for five days. Five isolates with different colony morphologies were obtained. An initial screen of the pathogenicity of all isolates showed that only one isolate showed disease activity in banana crowns. This isolate, C1, showed grayish-white aerial mycelium in culture as described above and, after ten days, became black. We did a full pathogenicity test with C1 using ten individual banana fruits (cv. Williams Cavendish). Briefly, one disc (Ø of 5 mm) of the fungus with agar was placed on the acropetal part of the banana fruit (on the peel) and another piece in the crown without wounding. Inoculated fruit were in a humid chamber at 20 °C for 20 days. Uninoculated fruits constituted the control. Isolate C1 caused 100% of the fruit and crowns to rot, with symptoms similar to those initially observed from fruit collected at the postharvest process (Fig. S1d). The fungus was re-isolated from symptomatic tissue, and its identity was confirmed through morphological characteristics consistent with Lasiodiplodia sp. Matured conidia of all mono hyphal strains (Fig. S1b) appeared dark brown with a single septum, having an ovate shape, and displayed longitudinal striations along their thickened walls (Fig. S1c). The dimensions of the mature conidia ranged from 16.02 - 26.85 x 11.09 - 16.74 µm (n = 60). Morphological characteristics showed similarity to Lasiodiplodia sp. (Alves et al., 2008). Microscopic observations were further confirmed by sequencing three loci: the internal transcribed spacer (ITS), β-tubulin, and partial translation elongation factor-1α (TEF-1α). Fungal genomic DNA from the C1 isolate was PCR amplified using ITS5/ITS4, EF1-728F/986R, and Bt2A/Bt2B primers, respectively, according to Glass & Donaldson (1995) and Bautista-Cruz et al. (2019). The resulting amplicons were sequenced, and those sequences were deposited in GenBank with the accession numbers ITS: PP532861, TEF-1α: PP551938, and β-tubulin: PP537587. Sequence alignment was conducted using ClustalW under the MEGA 11.0 software package (Tamura et al., 2021). Subsequently, phylogenetic analysis was performed using Bayesian inference using the BEAST v1.8.4 program (Drummond & Rambaut, 2007). The concatenated sequence of the isolate revealed clustering to the Lasiodiplodia theobromae clade, confirming its identity. To our knowledge, this is the first report of this pathogen causing CR on banana fruit in Ecuador. Based on the report of CR in the country, banana exporters and the Ecuadorian government should consider developing disease management methods that include the cultivation, shipping, ripening, and storage processes of the fruit.

Published

2024

5. Comparative Methods for Quantification of Sulfate-Reducing Bacteria in Environmental and Engineered Sludge Samples.

Author

Zambrano-Romero A, Ramirez-Villacis DX, Barriga-Medina N, Sierra-Alvarez R, Trueba G, Ochoa-Herrera V, and Leon-Reyes A

Abstract

This study aimed to compare microscopic counting, culture, and quantitative or real-time PCR (qPCR) to quantify sulfate-reducing bacteria in environmental and engineered sludge samples. Four sets of primers that amplified the dsrA and apsA gene encoding the two key enzymes of the sulfate-reduction pathway were initially tested. qPCR standard curves were constructed using genomic DNA from an SRB suspension and dilutions of an enriched sulfate-reducing sludge. According to specificity and reproducibility, the DSR1F/RH3-dsr-R primer set ensured a good quantification based on dsrA gene amplification; however, it exhibited inconsistencies at low and high levels of SRB concentrations in environmental and sulfate-reducing sludge samples. Ultimately, we conducted a qPCR method normalized to dsrA gene copies, using a synthetic double-stranded DNA fragment as a calibrator. This method fulfilled all validation criteria and proved to be specific, accurate, and precise. The enumeration of metabolically active SRB populations through culture methods differed from dsrA gene copies but showed a plausible positive correlation. Conversely, microscopic counting had limitations due to distinguishing densely clustered organisms, impacting precision. Hence, this study proves that a qPCR-based method optimized with dsrA gene copies as a calibrator is a sensitive molecular tool for the absolute enumeration of SRB populations in engineered and environmental sludge samples.

Published

2023

6. First Report of Alternaria alternata Causing Leaf Spot on Broccoli in Ecuador.

Author

Ramirez-Villacis D, Barriga-Medina N, Llerena-Llerena S, Pazmino-Guevara C, and Leon-Reyes A

Abstract

In Ecuador, broccoli (Brassica oleracea var. italica) production is located in the Andean region, specifically Cotopaxi-Ecuador (INEC, 2019). A leaf pathogen has been constantly observed in this area, showing brown circular necrosis surrounded by yellowish halo-like spots causing leaf death (Fig. 1a). This pathogen was believed to be Alternaria sp.; however, the species was not determined either using classical or molecular tools. In 2021, ten leaves showing similar symptoms were collected in Cotopaxi and sent for pathogen identification. Here, leaf explants (0.25 cm2) showing disease symptoms were surface sterilized with 2% sodium hypochlorite (NaClO) and 70% ethanol (C2H6O), rinsed with sterile water, and transferred to Potato Dextrose Agar (PDA) media. Petri dishes were incubated in darkness at 25°C for five days. The single hyphal tip method was used to purify the cultures on PDA. Fifteen pure isolates were obtained after incubating for 14 days. Isolates were incubated under blacklight for two days to induce fungal sporulation. All isolates presented early white cotton-like mycelium that later became dark green (Fig 1b). Under the microscope, we observed straight primary conidia in simple or branched chains. Also, the conidia were obclavate, long ellipsoids, moderate in size (19.5-43.9 μm in length, 7.1-17.2 μm in width), and septate with few longitudinal septa. Lastly, the conidium body can narrow itself into a secondary conidia (Fig 1c) (Woudenberg et al., 2013). According to colony and conidia morphology, isolates were identified as Alternaria sp. (Woudenberg et al., 2013). Five isolates were randomly selected for DNA extraction and sequencing of ITS (internal transcribed spacer; Chou, H.H. and Wu, W.S. 2002), TEF (translation elongation factor; O'Donnell et al., 1998), and RPB2 (RNA polymerase II second largest subunit; Liu et al., 1999) gene regions. DNA sequences obtained from each marker were identical for all isolates. Consensus sequences and alignment were built using ClustalX in MEGA X (Kumar et al., 2018). Consensus sequences were deposited in GenBank with the following accession numbers: ITS, ON982232; TEF, ON983964; RPB2, ON983963. A multilocus Bayesian inference phylogenetic tree was constructed in Beast software (version 1.8.4) using the concatenated sequences (Drummond et al., 2012; Maharachchikumbura et al., 2014). The isolates in our study clustered with isolates of Alternaria alternata, confirming their identity (Figure 2). For Koch's postulates, healthy broccoli plants were grown in sterile soil for six weeks. The fungal conidia were suspended in sterile distilled water (1×106 conidia/ml), and the leaves were inoculated by spraying the spore solution. The control treatment was sprayed with sterile distilled water alone. Plants were maintained at 28°C and had more than 85% relative humidity (Sigillo et al., 2020). Seven days after inoculation, plants showed chlorosis and necrosis. Ten days later, 100% of the treated leaves presented brown circular necrosis (Fig. 1d). Control plants showed no disease symptoms. Re-isolation of the pathogen from the diseased leaf tissue was performed as previously described. The isolates presented the exact morphology of pure cultures obtained from field-diseased leaves. The pathogenicity test was performed twice. To our knowledge, this is the first report on A. alternata being the causal agent of leaf spot on broccoli in Ecuador. Disease diagnosis contributes to providing strategies against this pathogen. Further investigations are needed to find biological/chemical techniques or cultivar resistance to control this pathogen in broccoli.

Published

2023

7. Influence of Grafting on Rootstock Rhizosphere Microbiome Assembly in Rosa sp. 'Natal Brier'.

Author

Ramirez-Villacis DX, Erazo-Garcia P, Quijia-Pillajo J, Llerena-Llerena S, Barriga-Medina N, Jones CD, and Leon-Reyes A

Abstract

The root microbiome is vital in plant development and health and is highly influenced by crop cultural practices. Rose ( Rosa sp.) is the most popular cut flower worldwide. Grafting in rose production is a standard practice to increase yield, improve flower quality, or reduce root-associated pests and diseases. 'Natal Brier' is a standard rootstock used in most commercial operations in Ecuador and Colombia, leading countries in producing and exporting ornamentals. It is known that the rose scion genotype affects root biomass and the root exudate profile of grafted plants. However, little is known about the influence of the rose scion genotype on the rhizosphere microbiome. We examined the influence of grafting and scion genotype on the rhizosphere microbiome of the rootstock 'Natal Brier'. The microbiomes of the non-grafted rootstock and the rootstock grafted with two red rose cultivars were assessed using 16S rRNA and ITS sequencing. Grafting changed microbial community structure and function. Further, analysis of grafted plant samples revealed that the scion genotype highly influences the rootstock microbiome. Under the presented experimental conditions, the rootstock 'Natal Brier' core microbiome consisted of 16 bacterial and 40 fungal taxa. Our results highlight that the scion genotype influences root microbe's recruitment, which might also influence the functionality of assembled microbiomes.

Published

2023

8. Saponin determination, expression analysis and functional characterization of saponin biosynthetic genes in Chenopodium quinoa leaves.

Author

Fiallos-Jurado J, Pollier J, Moses T, Arendt P, Barriga-Medina N, Morillo E, Arahana V, de Lourdes Torres M, Goossens A, and Leon-Reyes A

Subjects

Chenopodium quinoa metabolism, Organ Specificity, Plant Proteins metabolism, Saponins metabolism, Chenopodium quinoa genetics, Gene Expression Regulation, Plant, Plant Proteins genetics, Saponins genetics

Abstract

Quinoa (Chenopodium quinoa Willd.) is a highly nutritious pseudocereal with an outstanding protein, vitamin, mineral and nutraceutical content. The leaves, flowers and seed coat of quinoa contain triterpenoid saponins, which impart bitterness to the grain and make them unpalatable without postharvest removal of the saponins. In this study, we quantified saponin content in quinoa leaves from Ecuadorian sweet and bitter genotypes and assessed the expression of saponin biosynthetic genes in leaf samples elicited with methyl jasmonate. We found saponin accumulation in leaves after MeJA treatment in both ecotypes tested. As no reference genes were available to perform qPCR in quinoa, we mined publicly available RNA-Seq data for orthologs of 22 genes known to be stably expressed in Arabidopsis thaliana using geNorm, NormFinder and BestKeeper algorithms. The quinoa ortholog of At2g28390 (Monensin Sensitivity 1, MON1) was stably expressed and chosen as a suitable reference gene for qPCR analysis. Candidate saponin biosynthesis genes were screened in the quinoa RNA-Seq data and subsequent functional characterization in yeast led to the identification of CqbAS1, CqCYP716A78 and CqCYP716A79. These genes were found to be induced by MeJA, suggesting this phytohormone might also modulate saponin biosynthesis in quinoa leaves. Knowledge of the saponin biosynthesis and its regulation in quinoa may aid the further development of sweet cultivars that do not require postharvest processing., (Copyright © 2016 Elsevier Ireland Ltd. All rights reserved.)

Published

2016