All terms in CMPO
Label | Id | Description |
---|---|---|
increased process quality | PATO_0002304 | [A quality of a process that has a value that is increased compared to normal or average.] |
decreased process quality | PATO_0002302 | [A quality of a process that has a value that is decreased compared to normal or average.] |
mass | PATO_0000125 | [A physical quality that inheres in a bearer by virtue of the proportion of the bearer's amount of matter.] |
positive regulation of cell communication | GO_0010647 | [Any process that increases the frequency, rate or extent of cell communication. Cell communication is the process that mediates interactions between a cell and its surroundings. Encompasses interactions such as signaling or attachment between one cell and another cell, between a cell and an extracellular matrix, or between a cell and any other aspect of its environment.] |
cell adhesion phenotype | CMPO_0000028 | [A phenotype where the attachment of a cell, either to another cell or to an underlying substrate such as the extracellular matrix, via cell adhesion molecules is observed] |
spiny shaped cell phenotype | CMPO_0000268 | [A phenotype observation at the level of the cell shape where the cell has a star-like or bristly shape] |
organelle shape phenotype | CMPO_0000026 | [A collection of qualities that inhere in a cellular organelle relating to the organelle's shape] |
nucleus shape phenotype | CMPO_0000027 | [A collection of qualities that inhere in the nucleus relating to the ratios of distances between its features (points, edges, surfaces and also holes etc).] |
increased variability of cell size in population | CMPO_0000269 | [A population of cells where the cells exhibit a high variability of size] |
asymmetric lamellipodia phenotype | CMPO_0000266 | [A phenotype observation where more lamellipoda is localised to one side of the cell with respect to the other] |
lamellipodium phenotype | CMPO_0000279 | [A phenotype observation at the level of a cell with an increased amount of lamellipodia. ] |
star shaped cell phenotype | CMPO_0000267 | [A phenotype observation at the level of the cell shape where the cell has a star-like or bristly shape] |
golgi phenotype | CMPO_0000022 | [A collection of qualities that inhere in any constituent part of the Golgi apparatus, a compound membranous cytoplasmic organelle of eukaryotic cells, consisting of flattened, ribosome-free vesicles arranged in a more or less regular stack] |
fewer cells in M phase | CMPO_0000264 | [decreased occurrence of mitotic cells in population] |
mitochondrion phenotype | CMPO_0000023 | [A collection of qualities that inhere in any constituent part of a mitochondrion, a semiautonomous, self replicating organelle that occurs in varying numbers, shapes, and sizes in the cytoplasm of virtually all eukaryotic cells.] |
M phase mitotic phenotype | CMPO_0000265 | [A phenotype observation at the level of the M phase of the mitotic cell cycle] |
cytoskeletal phenotype | CMPO_0000020 | [A collection of qualities that inhere in any constituent part of the cytoskeleton, a cellular scaffolding or skeleton that maintains cell shape, enables some cell motion (using structures such as flagella and cilia), and plays important roles in both intra-cellular transport (e.g. the movement of vesicles and organelles) and cellular division. Includes constituent parts of intermediate filaments, microfilaments, microtubules, and the microtrabecular lattice.] |
apoptotic DNA | CMPO_0000262 | [Fragmented and condensed DNA during or following apoptosis] |
cell DNA phenotype | CMPO_0000176 | [A phenotype observation at the level of the cell DNA] |
I-kappaB kinase/NF-kappaB signaling | GO_0007249 | [The process in which a signal is passed on to downstream components within the cell through the I-kappaB-kinase (IKK)-dependent activation of NF-kappaB. The cascade begins with activation of a trimeric IKK complex (consisting of catalytic kinase subunits IKKalpha and/or IKKbeta, and the regulatory scaffold protein NEMO) and ends with the regulation of transcription of target genes by NF-kappaB. In a resting state, NF-kappaB dimers are bound to I-kappaB proteins, sequestering NF-kappaB in the cytoplasm. Phosphorylation of I-kappaB targets I-kappaB for ubiquitination and proteasomal degradation, thus releasing the NF-kappaB dimers, which can translocate to the nucleus to bind DNA and regulate transcription.] |