Nathan J. Ricks scite author profile

Gut -associated microbes (‘gut microbiota’) impact the nutrition of their hosts, especially in ruminants and pseudoruminants that consume high-cellulose diets. Examples include the pseudoruminant alpaca. To better understand how body site and diet influence the alpaca microbiota, we performed three 16S rRNA gene surveys. First, we surveyed the compartment 1 (C1), duodenum, jejunum, ileum, cecum, and large intestine (LI) of alpacas fed a grass hay (GH; tall fescue) or alfalfa hay (AH) diet for 30 days. Second, we performed a C1 survey of alpacas fed a series of 2-week mixed grass hay (MGH) diets supplemented with ∼25% dry weight barley, quinoa, amaranth, or soybean meal. Third, we examined the microbial differences of alpacas with normal versus poor body condition. Samples from GH- and AH-fed alpacas grouped by diet and body site but none of the four supplements significantly altered C1 microbiota composition, relative to each other, and none of the OTUs were differentially abundant between alpacas with normal versus poor body conditions. Taken together, the findings of a diet- and body-site specific alpaca microbiota are consistent with previous findings in ruminants and other mammals, but we provide no evidence to link changes in alpaca body condition with variation in microbiota relative abundance or identity.

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Investigating the genetic diversity and differentiation patterns in the Penstemon scariosus species complex under different sample sizes using AFLPs and SSRs

Rodríguez-Peña

Johnson

et al. 2018

Conserv Genet

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Habitat fragmentation due to anthropogenic activities is the major cause of biodiversity loss. Endemic and narrowly distributed species are the most susceptible to habitat degradation. Penstemon scariosus is one of many species whose natural habitat is vulnerable to industrialization. All varieties of P. scariosus (P. scariosus var. albifluvis, P. scariosus var. cyanomontanus, P. scariosus var. garrettii, P. scariosus var. scariosus) have small distribution ranges, but only P. scariosus var. albifluvis is being considered for listing under the Endangered Species Act. We used eight microsatellites or simple sequence repeats (SSRs) loci and two amplified fragment length polymorphism (AFLP) primer combinations to investigate the population genetic structure and diversity of P. scariosus varieties. Moreover, we compared the utility of the two marker systems in conservation genetics and estimated an appropriate sample size in population genetic studies. Genetic differentiation among populations based on F st ranged from low to moderate (F st = 0.056-0.157) and from moderate to high when estimated with D es (D es = 0.15-0.32). Also, AMOVA analysis shows that most of the genetic variation is within populations. Inbreeding coefficients (F is) were high in all varieties (0.20-0.56). The Bayesian analysis, STRU CTU RE, identified three clusters from SSR data and four clusters from AFLPs. Clusters were not consistent between marker systems and did not represent the current taxonomy. MEMGENE revealed that a high proportion of the genetic variation is due to geographic distance (R 2 = 0.38, P = 0.001). Comparing the genetic measurements from AFLPs and SSRs, we found that AFLP results were more accurate than SSR results across sample size when populations were larger than 25 individuals. As sample size decreases, the estimates become less stable in both AFLP and SSR datasets. Finally, this study provides insight into the population genetic structure of these varieties, which could be used in conservation efforts.

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The Complete Plastome Sequence Of Penstemon fruticosus (Pursh) Greene (Plantaginaceae)

Ricks

Stettler

Stevens

2017

Mitochondrial DNA Part B

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The genus Penstemon is an emerging model for the study of continental adaptive radiation. We report here the first complete plastome sequence for this genus. The P. fruticosus (shrubby, or brush penstemon) plastome is 152,704 bp in length with a quadripartite structure consisting of a large single-copy region (83,693 bp) and a small single-copy region (17,820 bp) that are separated by two inverted repeats (25,594 bp). The plastome contained 24 tRNA genes, 8 rRNA genes, and 83 protein-coding genes for a total of 115 unique genes. Phylogenetic analysis of whole chloroplast sequences shows that the nearest relatives of P. fruticosus are the Plantago and Veronica genera in the Plantaginaceae family.

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A culture‐independent approach to understanding the role of soil fungal communities in Bromus tectorum stand failure

et al. 2021

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Cheatgrass (Bromus tectorum L.) is an invasive annual grass (Poaceae) that has colonized large portions of the Intermountain West. Cheatgrass stand failures have been observed throughout the invaded region, the cause of which may be related to the presence of several species of pathogenic fungi in the soil or surface litter. In this metabarcoding study, we compared the fungal communities between sites that have and have not experienced stand failure. Samples were taken from the soil and surface litter near Winnemucca, Nevada, and in Skull Valley, Utah. Our results show distinct fungal communities associated with stand failure based on both geography and sample type. In both the Winnemucca and Skull Valley surface litter, there was an elevated abundance of the endophyte Ramimonilia apicalis in samples that had experienced a stand failure. Winnemucca surface litter stand failure samples had an increased abundance of a potential pathogen in the genus Comoclathris. Skull Valley surface litter stand failure samples had an increased abundance of an undescribed new species in the Rustroemiaceae family which is responsible for the so‐called bleach blonde syndrome in cheatgrass, while the soils had an increased abundance of potential pathogens in the genera Olpidium and Monosporascus.

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The Genome Sequence of Weissella cibaria DmW_103, Isolated from Wild Drosophila

et al. 2017

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Nathan J. Ricks

Bacterial Communities in the Alpaca Gastrointestinal Tract Vary With Diet and Body Site

Investigating the genetic diversity and differentiation patterns in the Penstemon scariosus species complex under different sample sizes using AFLPs and SSRs

The Complete Plastome Sequence Of Penstemon fruticosus (Pursh) Greene (Plantaginaceae)

A culture‐independent approach to understanding the role of soil fungal communities in Bromus tectorum stand failure

The Genome Sequence of Weissella cibaria DmW_103, Isolated from Wild Drosophila

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