Your search keyword '"Livingston, Samuel J."' showing total 10 results

1. Building a biofactory: Constructing glandular trichomes in Cannabis sativa

Author

Hancock, Jessica, Livingston, Samuel J., and Samuels, Lacey

Published

2024

2. Parallel functional reduction in the mitochondria of apicomplexan parasites

Author

Keeling, Patrick J., Mtawali, Mahara, Trznadel, Morelia, Livingston, Samuel J., and Wakeman, Kevin C.

Published

2024

3. Genomic analyses of Symbiomonas scintillans show no evidence for endosymbiotic bacteria but does reveal the presence of giant viruses.

Author

Cho, Anna, Lax, Gordon, Livingston, Samuel J., Masukagami, Yumiko, Naumova, Mariia, Millar, Olivia, Husnik, Filip, and Keeling, Patrick J.

Subjects

GENOMICS, WOLBACHIA, WHOLE genome sequencing, VIRAL genomes, VIRUS-like particles, TRANSMISSION electron microscopy

Abstract

Symbiomonas scintillans Guillou et Chrétiennot-Dinet, 1999 is a tiny (1.4 μm) heterotrophic microbial eukaryote. The genus was named based on the presence of endosymbiotic bacteria in its endoplasmic reticulum, however, like most such endosymbionts neither the identity nor functional association with its host were known. We generated both amplification-free shotgun metagenomics and whole genome amplification sequencing data from S. scintillans strains RCC257 and RCC24, but were unable to detect any sequences from known lineages of endosymbiotic bacteria. The absence of endobacteria was further verified with FISH analyses. Instead, numerous contigs in assemblies from both RCC24 and RCC257 were closely related to prasinoviruses infecting the green algae Ostreococcus lucimarinus, Bathycoccus prasinos, and Micromonas pusilla (OlV, BpV, and MpV, respectively). Using the BpV genome as a reference, we assembled a near-complete 190 kbp draft genome encoding all hallmark prasinovirus genes, as well as two additional incomplete assemblies of closely related but distinct viruses from RCC247, and three similar draft viral genomes from RCC24, which we collectively call SsVs. A multi-gene tree showed the three SsV genome types branched within highly supported clades with each of BpV2, OlVs, and MpVs, respectively. Interestingly, transmission electron microscopy also revealed a 190 nm virus-like particle similar the morphology and size of the endosymbiont originally reported in S. scintillans. Overall, we conclude that S. scintillans currently does not harbour an endosymbiotic bacterium, but is associated with giant viruses. Author summary: Endosymbiotic bacteria are found in a wide variety of hosts across the tree of eukaryotes and have been proposed to be evolutionarily and ecologically significant, but in most cases, we know little to nothing about them. This is exemplified by the stramenopile flagellate Symbiomonas scintillans, where the bacterial endosymbiont that gave the genus its name remains unidentified and has no known function. Here we used multiple genomic sequencing methods on two strains of S. scintillans, and showed absence of the endobacteria belonging to common endosymbiotic lineages. Instead, we identified giant viruses similar to those infecting prasinophyte green algae. Although further experiments are needed to verify the nature of the viral association with S. scintillans, our study is reminiscent of how the first mimivirus (named for mimicking gram-negative bacteria) was discovered, and we speculate similar discoveries will follow with ever-increasing genomic data of protists. [ABSTRACT FROM AUTHOR]

Published

2024

4. Coral-infecting parasites in cold marine ecosystems

Author

Trznadel, Morelia, Holt, Corey C., Livingston, Samuel J., Kwong, Waldan K., and Keeling, Patrick J.

Published

2024

5. To protect and emit beauty

Author

Livingston, Samuel J. and Samuels, A. Lacey

Published

2021

6. Overcoming the challenges of preserving lipid‐rich Cannabis sativa L. glandular trichomes for transmission electron microscopy.

Author

Livingston, Samuel J., Chou, Eva Yi, Quilichini, Teagen D., Page, Jonathan E., and Samuels, A. Lacey

Subjects

*CANNABIS (Genus), *TRANSMISSION electron microscopy, *CANNABINOIDS, *CANNABIDIOL, *TRICHOMES, *CELL preservation, *ELECTRON density, *GERMPLASM

Abstract

Cannabis glandular trichomes produce and store an abundance of lipidic specialised metabolites (e.g. cannabinoids and terpenes) that are consumed by humans for medicinal and recreational purposes. Due to a lack of genetic resources and inherent autofluorescence of cannabis glandular trichomes, our knowledge of cannabinoid trafficking and secretion is limited to transmission electron microscopy (TEM). Advances in cryofixation methods has resulted in ultrastructural observations closer to the 'natural state' of the living cell, and recent reports of cryofixed cannabis trichome ultrastructure challenge the long‐standing model of cannabinoid trafficking proposed by ultrastructural reports using chemically fixed samples. Here, we compare the ultrastructural morphology of cannabis glandular trichomes preserved using conventional chemical fixation and ultrarapid cryofixation. We show that chemical fixation results in amorphous metabolite inclusions surrounding the organelles of glandular trichomes that were not present in cryofixed samples. Vacuolar morphology in cryofixed samples exhibited homogenous electron density, while chemically fixed samples contained a flocculent electron dense periphery and electron lucent lumen. In contrast to the apparent advantages of cryopreservation, fine details of cell wall fibre orientation could be observed in chemically fixed glandular trichomes that were not seen in cryofixed samples. Our data suggest that chemical fixation results in intracellular artefacts that impact the interpretation of lipid production and trafficking, while enabling greater detail of extracellular polysaccharide organisation. LAY DESCRIPTION: For millennia humans have grown and consumed cannabis flowers for use in traditional medicine and intoxication, due to the plant's active ingredients called cannabinoids. The most well‐known cannabinoid is tetrahydrocannabidiol (THC). Despite this long history, and recent relaxation of cannabis uses for medicinal and recreational consumption in many parts of the world, little is known about how the plant makes the cannabinoids in its cells. Small mushroom‐shaped structures on the flower surface, called glandular trichomes, produce and store the cannabinoids. To image inside the cells of THC‐rich cannabis flowers, it is necessary to use electron microscopy, and this has revealed complex internal membrane networks and specialised cell structures in these tiny biofactories. In this study, we explored different ways to preserve the cannabis glandular trichomes for electron microscopy, using either cryogenic preservation or chemical crosslinking, in order to determine the benefits and drawbacks of each method. The chemical crosslinking method produced dramatic re‐arrangement of cell contents that were not seen in the cryofixation, where the near‐instantaneous immobilisation of the cell structure led to exceptional preservation of the THC‐producing cells. Despite the benefits of using cryofixation for preserving the complex cell structures, it was not as useful for seeing details of the cell walls surrounding the glandular trichome. Together, our data show stark differences in cannabis glandular trichome cell structure that result from cryofixation and chemical fixation. This is important because the chemical fixation protocol was historically used and informed previous models of cannabinoid production and trafficking. Cryofixation produces exciting new models of THC production in cannabis, due to its high‐fidelity preservation of cell structures. In contrast, studies of cell walls may still benefit from the traditional chemical cross‐linking technique of sample preservation for electron microscopy. https://www.cell.com/current‐biology/fulltext/S0960‐9822(22)01115‐0 [ABSTRACT FROM AUTHOR]

Published

2023

7. Cannabis Glandular Trichome Cell Walls Undergo Remodeling to Store Specialized Metabolites.

Author

Livingston, Samuel J, Bae, Eun Jeong, Unda, Faride, Hahn, Michael G, Mansfield, Shawn D, Page, Jonathan E, and Samuels, A Lacey

Subjects

*CANNABIS (Genus), *METABOLITES, *MONOSACCHARIDES, *CANNABIDIOL, *XYLOGLUCANS, *CELL membranes, *ARABINOGALACTAN

Abstract

The valuable cannabinoid and terpenoid metabolites of Cannabis sativa L. are produced by floral glandular trichomes. The trichomes consist of secretory disk cells, which produce the abundant lipidic metabolites, and an extracellular storage cavity. The mechanisms of apoplastic cavity formation to accumulate and store metabolites in cannabis glandular trichomes remain wholly unexplored. Here, we identify key wall components and how they change during cannabis trichome development. While glycome and monosaccharide analyses revealed that glandular trichomes have loosely bound xyloglucans and pectic polysaccharides, quantitative immunolabeling with wall-directed antibodies revealed precise spatiotemporal distributions of cell wall epitopes. An epidermal-like identity of early trichome walls matured into specialized wall domains over development. Cavity biogenesis was marked by separation of the subcuticular wall from the underlying surface wall in a homogalacturonan and α-1,5 arabinan epitope-rich zone and was associated with a reduction in fucosylated xyloglucan epitopes. As the cavity filled, a matrix with arabinogalactan and α-1,5 arabinan epitopes enclosed the metabolite droplets. At maturity, the disk cells' apical wall facing the storage cavity accumulated rhamnogalacturonan-I epitopes near the plasma membrane. Together, these data indicate that cannabis glandular trichomes undergo spatiotemporal remodeling at specific wall subdomains to facilitate storage cavity formation and metabolite storage. [ABSTRACT FROM AUTHOR]

Published

2021

8. Cannabis glandular trichomes alter morphology and metabolite content during flower maturation.

Author

Livingston, Samuel J., Quilichini, Teagen D., Booth, Judith K., Wong, Darren C. J., Rensing, Kim H., Laflamme‐Yonkman, Jessica, Castellarin, Simone D., Bohlmann, Joerg, Page, Jonathan E., and Samuels, A. Lacey

Subjects

*TRICHOMES, *CANNABIS (Genus), *MEDICAL marijuana, *MORPHOLOGY, *BIOFLUORESCENCE, *MARIJUANA growing, *FLOWERS, *PLANT anatomy

Abstract

Summary: The cannabis leaf is iconic, but it is the flowers of cannabis that are consumed for the psychoactive and medicinal effects of their specialized metabolites. Cannabinoid metabolites, together with terpenes, are produced in glandular trichomes. Superficially, stalked and sessile trichomes in cannabis only differ in size and whether they have a stalk. The objectives of this study were: to define each trichome type using patterns of autofluorescence and secretory cell numbers, to test the hypothesis that stalked trichomes develop from sessile‐like precursors, and to test whether metabolic specialization occurs in cannabis glandular trichomes. A two‐photon microscopy technique using glandular trichome intrinsic autofluorescence was developed which demonstrated that stalked glandular trichomes possessed blue autofluorescence correlated with high cannabinoid levels. These stalked trichomes had 12–16 secretory disc cells and strongly monoterpene‐dominant terpene profiles. In contrast, sessile trichomes on mature flowers and vegetative leaves possessed red‐shifted autofluorescence, eight secretory disc cells and less monoterpene‐dominant terpene profiles. Moreover, intrinsic autofluorescence patterns and disc cell numbers supported a developmental model where stalked trichomes develop from apparently sessile trichomes. Transcriptomes of isolated floral trichomes revealed strong expression of cannabinoid and terpene biosynthetic genes, as well as uncharacterized genes highly co‐expressed with CBDA synthase. Identification and characterization of two previously unknown and highly expressed monoterpene synthases highlighted the metabolic specialization of stalked trichomes for monoterpene production. These unique properties and highly expressed genes of cannabis trichomes determine the medicinal, psychoactive and sensory properties of cannabis products. Significance Statement: The unique monoterpene‐rich cannabis stalked trichomes that determine the medicinal, psychoactive and sensory properties of cannabis flowers develop from sessile‐like intermediates. [ABSTRACT FROM AUTHOR]

Published

2020

9. The ARM Domain of ARMADILLO-REPEAT KINESIN 1 is Not Required for Microtubule Catastrophe But Can Negatively Regulate NIMA-RELATED KINASE 6 in Arabidopsis thaliana.

Author

Eng, Ryan C., Halat, Laryssa S., Livingston, Samuel J., Tatsuya Sakai, Hiroyasu Motose, and Wasteneys, Geoffrey O.

Subjects

KINESIN, KINASES, PLANT microtubules, ARABIDOPSIS thaliana, ROOT hairs (Botany), PLANT morphogenesis

Abstract

Microtubules are dynamic filaments, the assembly and disassembly of which are under precise control of various associated proteins, including motor proteins and regulatory enzymes. In Arabidopsis thaliana, two such proteins are the ARMADILLO-REPEAT KINESIN 1 (ARK1), which promotes microtubule disassembly, and the NIMA-RELATED KINASE 6 (NEK6), which has a role in organizing microtubule arrays. Previous yeast two-hybrid and in vitro pull-down assays determined that NEK6 can interact with ARK1 through the latter protein's Armadillo-repeat (ARM) cargo domain. To explore the function of the ARM domain, we generated fluorescent reporter fusion proteins to ARK1 lacking the ARM domain (ARK1ΔARM-GFP) and to the ARM domain alone (ARM-GFP). Both of these constructs strongly associated with the growing plus ends of microtubules, but only ARK1ΔARM-GFP was capable of inducing microtubule catastrophe and rescuing the ark1-1 root hair phenotype. These results indicate that neither the ARM domain nor NEK6's putative interaction with it is required for ARK1 to induce microtubule catastrophe. In further exploration of the ARK1-NEK6 relationship, we demonstrated that, despite evidence that NEK6 can phosphorylate ARK1 in vitro, the in vivo distribution and function of ARK1 were not affected by the loss of NEK6, and vice versa. Moreover, NEK6 and ARK1 were found to have overlapping but non-identical distribution on microtubules, and hormone treatments known to affect NEK6 activity did not stimulate interaction. These findings suggest that ARK1 and NEK6 function independently in microtubule dynamics and cell morphogenesis. Despite the results of this functional analysis, we found that overexpression of the ARM domain led to complete loss of NEK6 transcription, suggesting that the ARM domain might have a regulatory role in NEK6 expression. [ABSTRACT FROM AUTHOR]

Published

2017

10. A polarized supercell produces specialized metabolites in cannabis trichomes.

Author

Livingston, Samuel J., Rensing, Kim H., Page, Jonathan E., and Samuels, A. Lacey

Subjects

*CANNABIS (Genus), *IMMUNOGOLD labeling, *TRICHOMES, *METABOLITES, *SYNTHETIC biology, *STEREOLOGY, *CANNABINOID receptors, *MEMBRANE fusion

Abstract

For centuries, humans have cultivated cannabis for the pharmacological properties that result from consuming its specialized metabolites, primarily cannabinoids and terpenoids. Today, cannabis is a multi-billion-dollar industry whose existence rests on the biological activity of tiny cell clusters, called glandular trichomes, found mainly on flowers. Cannabinoids are toxic to cannabis cells,1 and how the trichome cells can produce and secrete massive quantities of lipophilic metabolites is not known. 1 To address this gap in knowledge, we investigated cannabis glandular trichomes using ultra-rapid cryofixation, quantitative electron microscopy, and immuno-gold labeling of cannabinoid pathway enzymes. We demonstrate that the metabolically active cells in cannabis form a "supercell," with extensive cytoplasmic bridges across the cell walls and a polar distribution of organelles adjacent to the apical surface where metabolites are secreted. The predicted metabolic role of the non-photosynthetic plastids is supported by unusual membrane arrays in the plastids and the localization of the start of the cannabinoid/terpene pathway in the stroma of the plastids. Abundant membrane contact sites connected plastid paracrystalline cores with the plastid envelope, plastid with endoplasmic reticulum (ER), and ER with plasma membrane. The final step of cannabinoid biosynthesis, catalyzed by tetrahydrocannabinolic acid synthase (THCAS), was localized in the cell-surface wall facing the extracellular storage cavity. We propose a new model of how the cannabis cells can support abundant metabolite production, with emphasis on the key role of membrane contact sites and extracellular THCA biosynthesis. This new model can inform synthetic biology approaches for cannabinoid production in yeast or cell cultures. • Glandular cells form a polarized syncytium during THCA production and secretion • GPPS is located in plastids that contain conspicuous membrane fusions • THCAS is located exclusively on the extracellular surface of trichomes • Membrane contacts among plastids, ER, and PM inform a new trafficking model Cannabinoids and terpenes are biosynthesized, secreted, and stored in cannabis glandular trichomes. Livingston et al. reveal the nanoscale distribution of the enzymes involved in cannabinoid biosynthesis and the unique cellular environment where these enzymes operate. A new model of metabolite trafficking from the plastid to the cell wall is proposed. [ABSTRACT FROM AUTHOR]

Published

2022