Your search keyword '"Alveolata metabolism"' showing total 3 results

1. The transcriptome of the rumen ciliate Entodinium caudatum reveals some of its metabolic features.

Author

Wang L, Abu-Doleh A, Plank J, Catalyurek UV, Firkins JL, and Yu Z

Subjects

Alveolata cytology, Alveolata physiology, Animals, Carbohydrate Metabolism genetics, Intracellular Space metabolism, Phagocytosis genetics, RNA, Messenger genetics, RNA-Seq, Signal Transduction genetics, Symbiosis genetics, Alveolata genetics, Alveolata metabolism, Gene Expression Profiling

Abstract

Background: Rumen ciliates play important roles in rumen function by digesting and fermenting feed and shaping the rumen microbiome. However, they remain poorly understood due to the lack of definitive direct evidence without influence by prokaryotes (including symbionts) in co-cultures or the rumen. In this study, we used RNA-Seq to characterize the transcriptome of Entodinium caudatum, the most predominant and representative rumen ciliate species., Results: Of a large number of transcripts, > 12,000 were annotated to the curated genes in the NR, UniProt, and GO databases. Numerous CAZymes (including lysozyme and chitinase) and peptidases were represented in the transcriptome. This study revealed the ability of E. caudatum to depolymerize starch, hemicellulose, pectin, and the polysaccharides of the bacterial and fungal cell wall, and to degrade proteins. Many signaling pathways, including the ones that have been shown to function in E. caudatum, were represented by many transcripts. The transcriptome also revealed the expression of the genes involved in symbiosis, detoxification of reactive oxygen species, and the electron-transport chain. Overall, the transcriptomic evidence is consistent with some of the previous premises about E. caudatum. However, the identification of specific genes, such as those encoding lysozyme, peptidases, and other enzymes unique to rumen ciliates might be targeted to develop specific and effective inhibitors to improve nitrogen utilization efficiency by controlling the activity and growth of rumen ciliates. The transcriptomic data will also help the assembly and annotation in future genomic sequencing of E. caudatum., Conclusion: As the first transcriptome of a single species of rumen ciliates ever sequenced, it provides direct evidence for the substrate spectrum, fermentation pathways, ability to respond to various biotic and abiotic stimuli, and other physiological and ecological features of E. caudatum. The presence and expression of the genes involved in the lysis and degradation of microbial cells highlight the dependence of E. caudatum on engulfment of other rumen microbes for its survival and growth. These genes may be explored in future research to develop targeted control of Entodinium species in the rumen. The transcriptome can also facilitate future genomic studies of E. caudatum and other related rumen ciliates.

Published

2019

2. Identification of divergent WH2 motifs by HMM-HMM alignments.

Author

Weiß CL and Schultz J

Subjects

Actin Cytoskeleton chemistry, Actin Cytoskeleton metabolism, Actins chemistry, Alveolata chemistry, Alveolata metabolism, Amino Acid Motifs, Amino Acid Sequence, Animals, Drosophila Proteins metabolism, Drosophila melanogaster chemistry, Drosophila melanogaster metabolism, Euglenozoa chemistry, Euglenozoa metabolism, Fungi chemistry, Fungi metabolism, Mice, Microfilament Proteins metabolism, Molecular Sequence Data, Nerve Tissue Proteins metabolism, Protein Binding, Sequence Alignment methods, Thymosin chemistry, Thymosin metabolism, Ubiquitins metabolism, Actins metabolism, Drosophila Proteins chemistry, Microfilament Proteins chemistry, Nerve Tissue Proteins chemistry, Protein Interaction Domains and Motifs, Sequence Alignment statistics & numerical data, Thymosin analogs & derivatives, Ubiquitins chemistry

Abstract

Background: The actin cytoskeleton is a hallmark of eukaryotic cells. Its regulation as well as its interaction with other proteins is carefully orchestrated by actin interaction domains. One of the key players is the WH2 motif, which enables binding to actin monomers and filaments and is involved in the regulation of actin nucleation. Contrasting conserved domains, the identification of this motif in protein sequences is challenging, as it is short and poorly conserved., Findings: To identify divergent members, we combined Hidden-Markov-Model (HMM) to HMM alignments with orthology predictions. Thereby, we identified nearly 500 proteins containing so far not annotated WH2 motifs. This included shootin-1, an actin binding protein involved in neuron polarization. Among others, WH2 motifs of 'proximal to raf' (ptr)-orthologs, which are described in the literature, but not annotated in genome databases, were identified., Conclusion: In summary, we increased the number of WH2 motif containing proteins substantially. This identification of candidate regions for actin interaction could steer their experimental characterization. Furthermore, the approach outlined here can easily be adapted to the identification of divergent members of further domain families.

Published

2015

3. Transcriptome analysis reveals nuclear-encoded proteins for the maintenance of temporary plastids in the dinoflagellate Dinophysis acuminata.

Author

Wisecaver JH and Hackett JD

Subjects

Alveolata metabolism, Ciliophora cytology, Ciliophora genetics, Ciliophora metabolism, Cryptophyta cytology, Cryptophyta genetics, Cryptophyta metabolism, Evolution, Molecular, Peptides genetics, Peptides metabolism, Phylogeny, Sequence Analysis, DNA, Alveolata cytology, Alveolata genetics, Cell Nucleus genetics, Gene Expression Profiling, Plastids metabolism, Protozoan Proteins genetics, Protozoan Proteins metabolism

Abstract

Background: Dinophysis is exceptional among dinoflagellates, possessing plastids derived from cryptophyte algae. Although Dinophysis can be maintained in pure culture for several months, the genus is mixotrophic and needs to feed either to acquire plastids (a process known as kleptoplastidy) or obtain growth factors necessary for plastid maintenance. Dinophysis does not feed directly on cryptophyte algae, but rather on a ciliate (Myrionecta rubra) that has consumed the cryptophytes and retained their plastids. Despite the apparent absence of cryptophyte nuclear genes required for plastid function, Dinophysis can retain cryptophyte plastids for months without feeding., Results: To determine if this dinoflagellate has nuclear-encoded genes for plastid function, we sequenced cDNA from Dinophysis acuminata, its ciliate prey M. rubra, and the cryptophyte source of the plastid Geminigera cryophila. We identified five proteins complete with plastid-targeting peptides encoded in the nuclear genome of D. acuminata that function in photosystem stabilization and metabolite transport. Phylogenetic analyses show that the genes are derived from multiple algal sources indicating some were acquired through horizontal gene transfer., Conclusions: These findings suggest that D. acuminata has some functional control of its plastid, and may be able to extend the useful life of the plastid by replacing damaged transporters and protecting components of the photosystem from stress. However, the dearth of plastid-related genes compared to other fully phototrophic algae suggests that D. acuminata does not have the nuclear repertoire necessary to maintain the plastid permanently.

Published

2010