scholarly journals Evolution of irreversible somatic differentiation

eLife ◽  
2021 ◽  
Vol 10 ◽  
Author(s):  
Yuanxiao Gao ◽  
Hye Jin Park ◽  
Arne Traulsen ◽  
Yuriy Pichugin
Keyword(s):  
Cell Differentiation ◽  
Vegetative Cell ◽  
Evolutionary Model ◽  
Life Forms ◽  
Multicellular Organism ◽  
Vegetative Cells ◽  
Key Innovation ◽  
Primitive Species ◽  
Three Components

A key innovation emerging in complex animals is irreversible somatic differentiation: daughters of a vegetative cell perform a vegetative function as well, thus, forming a somatic lineage that can no longer be directly involved in reproduction. Primitive species use a different strategy: vegetative and reproductive tasks are separated in time rather than in space. Starting from such a strategy, how is it possible to evolve life forms which use some of their cells exclusively for vegetative functions? Here, we develop an evolutionary model of development of a simple multicellular organism and find that three components are necessary for the evolution of irreversible somatic differentiation: (i) costly cell differentiation, (ii) vegetative cells that significantly improve the organism’s performance even if present in small numbers, and (iii) large enough organism size. Our findings demonstrate how an egalitarian development typical for loose cell colonies can evolve into germ-soma differentiation dominating metazoans.

scholarly journals Evolution of irreversible somatic differentiation

2021 ◽  
Author(s):  
Yuanxiao Gao ◽  
Hye Jin Park ◽  
Arne Traulsen ◽  
Yuriy Pichugin
Keyword(s):  
Cell Differentiation ◽  
Vegetative Cell ◽  
Evolutionary Model ◽  
Life Forms ◽  
Multicellular Organism ◽  
Vegetative Cells ◽  
Key Innovation ◽  
Primitive Species ◽  
Three Components

AbstractA key innovation emerging in complex animals is irreversible somatic differentiation: daughters of a vegetative cell perform a vegetative function as well, thus, forming a somatic lineage that can no longer be directly involved in reproduction. Primitive species use a different strategy: vegetative and reproductive tasks are separated in time rather than in space. Starting from such a strategy, how is it possible to evolve life forms which use some of their cells exclusively for vegetative functions? Here, we developed an evolutionary model of development of a simple multicellular organism and found that three components are necessary for the evolution of irreversible somatic differentiation: (i) costly cell differentiation, (ii) vegetative cells that significantly improve the organism’s performance even if present in small numbers, and (iii) large enough organism size. Our findings demonstrate how an egalitarian development typical for loose cell colonies can evolve into germ-soma differentiation dominating metazoans.

Basal Body and Flagellar Development During the Vegetative Cell Cycle and the Sexual Cycle of Chlamydomonas Reinhardii

1974 ◽  
Vol 16 (3) ◽  
pp. 529-556 ◽  
Author(s):  
T. CAVALIER-SMITH
Keyword(s):  
Basal Body ◽  
Vegetative Cell ◽  
Amorphous Material ◽  
Sexual Cycle ◽  
Transitional Region ◽  
Basal Bodies ◽  
Vegetative Cells ◽  
Chlamydomonas Reinhardii ◽  
Body Development ◽  
Microtubular Roots

Basal body development and flagellar regression and growth in the unicellular green alga Chlamydomonas reinhardii were studied by light and electron microscopy during the vegetative cell cycle in synchronous cultures and during the sexual life cycle. Flagella regress by gradual shortening prior to vegetative cell division and also a few hours after cell fusion in the sexual cycle. In vegetative cells basal bodies remain attached to the plasma membrane by their transitional fibres and do not act as centrioles at the spindle poles during division. In zygotes the basal bodies and associated microtubular roots and cross-striated connexions all dissolve, and by 6.5 h after mating all traces of flagellar apparatus and associated structures have disappeared. They remain absent for 6 days throughout zygospore maturation and then are reassembled during zygospore germination, after meiosis has begun. Basal body assembly in developing zygospores occurs close to the plasma membrane (in the absence of pre-existing basal bodies) via an intermediate stage consisting of nine single A-tubules surrounding a central ‘cartwheel’. Assembly is similar in vegetative cells (and occurs prior to cell division), except that new basal bodies are physically attached to old ones by amorphous material. In vegetative cells, amorphous disks, which may possibly be still earlier stages in basal-body development occur in the same location as 9-singlet developing basal bodies. After the 9-singlet structure is formed, B and C fibres are added and the basal body elongates to its mature length. Microtubular roots, striated connexions and flagella are then assembled. Both flagellar regression and growth are gradual and sequential, the transitional region at the base of the flagellum being formed first and broken down last. The presence of amorphous material at the tip of the axoneme of growing and regressing flagella suggests that the axoneme grows or shortens by the sequential assembly or disassembly at its tip. In homogenized cells basal bodies remain firmly attached to each other by their striated connexions. The flagellar transitional region, and parts of the membrane and of the 4 microtubular roots, also remain attached; so also do new developing basal bodies, if present. These structures are well preserved in homogenates and new fine-structural details can be seen. These results are discussed, and lend no support to the idea that basal bodies have genetic continuity. It is suggested that basal body development can be best understood if a distinction is made between the information needed to specify the structure of a basal body and that needed to specify its location and orientation.

Actin During Pollen Germination

1986 ◽  
Vol 86 (1) ◽  
pp. 1-8
Author(s):  
J. HESLOP-HARRISON ◽  
Y. HESLOP-HARRISON ◽  
M. CRESTI ◽  
A. TIEZZI ◽  
F. CIAMPOLINI
Keyword(s):  
Medium Release ◽  
Pollen Tube ◽  
Vegetative Cell ◽  
Pollen Germination ◽  
Pollen Grain ◽  
Actin Microfilaments ◽  
Vegetative Cells ◽  
Stage Of Development ◽  
Angiosperm Species

The cytoplasm of the vegetative cell of the ungerminated pollen grain of Endymton non-scriplus and other angiosperm species contains numerous fusiform bodies sometimes exceeding 15μm in length and 2.5 μm in width, which bind fluorescent-labelled phalloidin and are likely therefore to constitute a storage form of actin. The bodies are dispersed during the activation of the pollen, being replaced by aggregates of slender phalloidin-binding fibrils, which converge towards the germination apertures and are present in the emerging pollen tube. The storage bodies appear to be homologous with crystalline-fibrillar structures, shown in an earlier paper to be abundantly present in the vegetative cells of Nicotiana pollen. These are composed of massive aggregates of linearly disposed units with individual widths of 4–7 nm, probably to be interpreted as actin microfilaments. Vegetative-cell protoplasts from mature but ungerminated pollen disrupted in osmotically balancing medium release extended phalloidin-binding fibrils of a kind not observed in the intact grain. It is suggested that these are derived by the rapid dissociation of the compact actin storage bodies present in the vegetative cell at this stage of development.

scholarly journals DNA demethylation by ROS1a in rice vegetative cells promotes methylation in sperm

2019 ◽  
Vol 116 (19) ◽  
pp. 9652-9657 ◽  
Author(s):  
M. Yvonne Kim ◽  
Akemi Ono ◽  
Stefan Scholten ◽  
Tetsu Kinoshita ◽  
Daniel Zilberman ◽  
...  
Keyword(s):  
Dna Methylation ◽  
Vegetative Cell ◽  
Seed Viability ◽  
Dna Demethylation ◽  
Central Cell ◽  
Dna Glycosylase ◽  
Rice Seed ◽  
Vegetative Cells ◽  
Active Dna Demethylation ◽  
Cell Genome

Epigenetic reprogramming is required for proper regulation of gene expression in eukaryotic organisms. In Arabidopsis, active DNA demethylation is crucial for seed viability, pollen function, and successful reproduction. The DEMETER (DME) DNA glycosylase initiates localized DNA demethylation in vegetative and central cells, so-called companion cells that are adjacent to sperm and egg gametes, respectively. In rice, the central cell genome displays local DNA hypomethylation, suggesting that active DNA demethylation also occurs in rice; however, the enzyme responsible for this process is unknown. One candidate is the rice REPRESSOR OF SILENCING1a (ROS1a) gene, which is related to DME and is essential for rice seed viability and pollen function. Here, we report genome-wide analyses of DNA methylation in wild-type and ros1a mutant sperm and vegetative cells. We find that the rice vegetative cell genome is locally hypomethylated compared with sperm by a process that requires ROS1a activity. We show that many ROS1a target sequences in the vegetative cell are hypomethylated in the rice central cell, suggesting that ROS1a also demethylates the central cell genome. Similar to Arabidopsis, we show that sperm non-CG methylation is indirectly promoted by DNA demethylation in the vegetative cell. These results reveal that DNA glycosylase-mediated DNA demethylation processes are conserved in Arabidopsis and rice, plant species that diverged 150 million years ago. Finally, although global non-CG methylation levels of sperm and egg differ, the maternal and paternal embryo genomes show similar non-CG methylation levels, suggesting that rice gamete genomes undergo dynamic DNA methylation reprogramming after cell fusion.

Differences in formation of vegetative cells and their walls in Trebouxia and Pseudotrebouxia as further evidence for the classification of these genera

1985 ◽  
Vol 17 (3) ◽  
pp. 281-287 ◽  
Author(s):  
E. Peveling ◽  
J. König
Keyword(s):  
Vegetative Cell ◽  
Cell Walls ◽  
Vegetative Cells

AbstractThe formation of vegetative cells from zoospores and the morphogenesis of the multilayered cell walls during this process was observed in some Trebouxia and Pseudotrebouxia species. In Trebouxia species, e.g. Trebouxia erici, the wall of the vegetative cell is formed around the zoospore while in Pseudotrebouxia species, e.g. Pseudotrebouxia corticola, firstly an autosporangium with its wall is formed then the autosporangium further divides.

Presence of endotoxin in vegetative cells of Bacillus thuringiensis var. sotto

1970 ◽  
Vol 16 (9) ◽  
pp. 905-906 ◽  
Author(s):  
P. Luthy ◽  
Y. Hayashi ◽  
T. A. Angus
Keyword(s):  
Bacillus Thuringiensis ◽  
Vegetative Cell ◽  
Vegetative Cells ◽  
Cell Extracts

Endotoxin was found in vegetative cell extracts of Bacillus thuringiensis var. sotto. The distribution of the toxin in fractions obtained by centrifugation at different speeds indicates an association with cell particles, most likely membranes.

A SEROLOGICAL COMPARISON OF VEGETATIVE CELL AND ASCUS WALLS AND THE SPORE COAT OF SACCHAROMYCES CEREVISIAE

1966 ◽  
Vol 12 (3) ◽  
pp. 485-488 ◽  
Author(s):  
I. J. Snider ◽  
J. J. Miller
Keyword(s):  
Saccharomyces Cerevisiae ◽  
Protein Structure ◽  
Vegetative Cell ◽  
Proteolytic Enzyme ◽  
Spore Coat ◽  
Vegetative Cells

Cross-agglutination tests with sera obtained by injection of vegetative cells, asci, and spores into rabbits revealed no immunological distinction between the walls of vegetative cells and asci, whereas the spore coats were found to be serologically distinct from cell and ascus walls. Treatment of vegetative cells and asci with periodate or a proteolytic enzyme before agglutination tests gave results which suggest that the critical antigen is a protein structure.

scholarly journals cyAbrB transcriptional regulators as safety devices to inhibit heterocyst differentiation in Anabaena

2019 ◽  
Author(s):  
Akiyoshi Higo ◽  
Eri Nishiyama ◽  
Kota Nakamura ◽  
Yukako Hihara ◽  
Shigeki Ehira
Keyword(s):  
Cell Differentiation ◽  
Nitrogen Sources ◽  
Oxygenic Photosynthesis ◽  
Promoter Regions ◽  
Independent Manner ◽  
Vegetative Cells ◽  
Heterocyst Differentiation ◽  
Safety Devices ◽  
Unique Cell ◽  
Pcc 7120

AbstractCyanobacteria are monophyletic organisms that perform oxygenic photosynthesis. While they exhibit great diversity, they have a common set of genes. However, the essentiality of them for viability has hampered the elucidation of their functions. One example of the genes is cyabrB1 encoding a transcriptional regulator. In the present study, we investigated the function of cyabrB1 in heterocyst-forming cyanobacterium Anabaena sp. PCC 7120 through CRISPR interference, a method we recently utilized for the photosynthetic production of a useful chemical in the strain. Conditional knockdown of cyabrB1 in the presence of nitrate resulted in formation of heterocysts. Two genes, hetP and hepA, which are required for heterocyst formation, were up-regulated by cyabrB1 knockdown in the presence of combined nitrogen sources. The genes are known to be induced by HetR, a master regulator of heterocyst formation. hetR was not induced by cyabrB1 knockdown. hetP and hepA were repressed by direct binding of cyAbrB1 to their promoter regions in a HetR-independent manner. In addition, the over-expression of cyabrB1 abolished heterocyst formation upon nitrogen depletion. Also, knockout of cyabrB2, a paralogue gene of cyabrB1, in addition to cyabrB1 knockdown, enhanced heterocyst formation in the presence of nitrate, suggesting functional redundancy of cyAbrB proteins. We propose that a balance between amounts of HetR and cyAbrB1 is a key factor influencing heterocyst differentiation during nitrogen step-down. cyAbrB proteins are essential safety devices inhibiting heterocyst differentiation.ImportanceSpore formation in Bacillus subtilis and Streptomyces represents non-terminal differentiation and has been extensively studied as models of prokaryotic cell differentiation. In the two organisms, many cells differentiate simultaneously, and the differentiation is governed by a network in which one regulator stands at the top. Differentiation of heterocysts in Anabaena sp. PCC 7120 has also been extensively studied. The differentiation is unique because it is terminal and only 5-10% vegetative cells differentiate into heterocysts. In the present study, we identified cyAbrB1 as a repressor of two genes that are essential for heterocyst formation, hetP and hepA, independent of HetR, which is a master activator for heterocyst differentiation. The finding is reasonable for unique cell differentiation of Anabaena because cyAbrB1 could suppress heterocyst differentiation tightly in vegetative cells, while only cells in which HetR is over-expressed could differentiate into heterocysts.

scholarly journals Cell-specific cis-natural antisense transcripts (cis-NATs) in the sperm and the pollen vegetative cells of Arabidopsis thaliana

F1000Research ◽  
2018 ◽  
Vol 7 ◽  
pp. 93
Author(s):  
Peng Qin ◽  
Ann E. Loraine ◽  
Sheila McCormick
Keyword(s):  
Gene Expression ◽  
Vegetative Cell ◽  
Cell Types ◽  
Antisense Transcripts ◽  
Vegetative Cells ◽  
Natural Antisense Transcripts ◽  
Protein Coding ◽  
Regulate Gene Expression ◽  
Genome Wide ◽  
Gene Models

Background: cis-NATs (cis-natural antisense transcripts) are transcribed from opposite strands of adjacent genes and have been shown to regulate gene expression by generating small RNAs from the overlapping region. cis-NATs are important for plant development and resistance to pathogens and stress. Several genome-wide investigations identified a number of cis-NAT pairs, but these investigations predicted cis-NATS using expression data from bulk samples that included lots of cell types. Some cis-NAT pairs identified from those investigations might not be functional, because both transcripts of cis-NAT pairs need to be co-expressed in the same cell. Pollen only contains two cell types, two sperm and one vegetative cell, which makes cell-specific investigation of cis-NATs possible. Methods: We investigated potential protein-coding cis-NATs in pollen and sperm using pollen RNA-seq data and TAIR10 gene models using the Integrated Genome Browser.  We then used sperm microarray data and sRNAs in sperm and pollen to determine possibly functional cis-NATs in the sperm or vegetative cell, respectively. Results: We identified 1471 potential protein-coding cis-NAT pairs, including 131 novel pairs that were not present in TAIR10 gene models. In pollen, 872 possibly functional pairs were identified. 72 and 56 pairs were potentially functional in sperm and vegetative cells, respectively. sRNAs were detected at 794 genes, belonging to 739 pairs. Conclusion: These potential candidates in sperm and the vegetative cell are tools for understanding gene expression mechanisms in pollen.

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