If R <- P o Q is a defining property chain axiom, then it also holds that R -> P o Q. Note that this cannot be expressed directly in OWL
is a defining property chain axiom
If R <- P o Q is a defining property chain axiom, then (1) R -> P o Q holds and (2) Q is either reflexive or locally reflexive. A corollary of this is that P SubPropertyOf R.
is a defining property chain axiom where second argument is reflexive
preceded by
x is preceded by y if and only if the time point at which y ends is before or equivalent to the time point at which x starts. Formally: x preceded by y iff ω(y) <= α(x), where α is a function that maps a process to a start point, and ω is a function that maps a process to an end point.
An example is: translation preceded_by transcription; aging preceded_by development (not however death preceded_by aging). Where derives_from links classes of continuants, preceded_by links classes of processes. Clearly, however, these two relations are not independent of each other. Thus if cells of type C1 derive_from cells of type C, then any cell division involving an instance of C1 in a given lineage is preceded_by cellular processes involving an instance of C. The assertion P preceded_by P1 tells us something about Ps in general: that is, it tells us something about what happened earlier, given what we know about what happened later. Thus it does not provide information pointing in the opposite direction, concerning instances of P1 in general; that is, that each is such as to be succeeded by some instance of P. Note that an assertion to the effect that P preceded_by P1 is rather weak; it tells us little about the relations between the underlying instances in virtue of which the preceded_by relation obtains. Typically we will be interested in stronger relations, for example in the relation immediately_preceded_by, or in relations which combine preceded_by with a condition to the effect that the corresponding instances of P and P1 share participants, or that their participants are connected by relations of derivation, or (as a first step along the road to a treatment of causality) that the one process in some way affects (for example, initiates or regulates) the other.
is preceded by
preceded_by
http://www.obofoundry.org/ro/#OBO_REL:preceded_by
preceded by
precedes
x precedes y if and only if the time point at which x ends is before or equivalent to the time point at which y starts. Formally: x precedes y iff ω(x) <= α(y), where α is a function that maps a process to a start point, and ω is a function that maps a process to an end point.
precedes
occurs in
b occurs_in c =def b is a process and c is a material entity or immaterial entity& there exists a spatiotemporal region r and b occupies_spatiotemporal_region r.& forall(t) if b exists_at t then c exists_at t & there exist spatial regions s and s’ where & b spatially_projects_onto s at t& c is occupies_spatial_region s’ at t& s is a proper_continuant_part_of s’ at t
occurs_in
unfolds in
unfolds_in
Paraphrase of definition: a relation between a process and an independent continuant, in which the process takes place entirely within the independent continuant
occurs in
site of
[copied from inverse property 'occurs in'] b occurs_in c =def b is a process and c is a material entity or immaterial entity& there exists a spatiotemporal region r and b occupies_spatiotemporal_region r.& forall(t) if b exists_at t then c exists_at t & there exist spatial regions s and s’ where & b spatially_projects_onto s at t& c is occupies_spatial_region s’ at t& s is a proper_continuant_part_of s’ at t
Paraphrase of definition: a relation between an independent continuant and a process, in which the process takes place entirely within the independent continuant
contains process
participates in
this blood clot participates in this blood coagulation
this input material (or this output material) participates in this process
this investigator participates in this investigation
a relation between a continuant and a process, in which the continuant is somehow involved in the process
participates_in
participates in
has participant
this blood coagulation has participant this blood clot
this investigation has participant this investigator
this process has participant this input material (or this output material)
a relation between a process and a continuant, in which the continuant is somehow involved in the process
Has_participant is a primitive instance-level relation between a process, a continuant, and a time at which the continuant participates in some way in the process. The relation obtains, for example, when this particular process of oxygen exchange across this particular alveolar membrane has_participant this particular sample of hemoglobin at this particular time.
has_participant
http://www.obofoundry.org/ro/#OBO_REL:has_participant
has participant
dos
2017-09-17T13:52:24Z
Process(P2) is directly regulated by process(P1) iff: P1 regulates P2 via direct physical interaction between an agent executing P1 (or some part of P1) and an agent executing P2 (or some part of P2). For example, if protein A has protein binding activity(P1) that targets protein B and this binding regulates the kinase activity (P2) of protein B then P1 directly regulates P2.
directly regulated by
Process(P2) is directly regulated by process(P1) iff: P1 regulates P2 via direct physical interaction between an agent executing P1 (or some part of P1) and an agent executing P2 (or some part of P2). For example, if protein A has protein binding activity(P1) that targets protein B and this binding regulates the kinase activity (P2) of protein B then P1 directly regulates P2.
GOC:dos
Process(P2) is directly negatively regulated by process(P1) iff: P1 negatively regulates P2 via direct physical interaction between an agent executing P1 (or some part of P1) and an agent executing P2 (or some part of P2). For example, if protein A has protein binding activity(P1) that targets protein B and this binding negatively regulates the kinase activity (P2) of protein B then P2 directly negatively regulated by P1.
dos
2017-09-17T13:52:38Z
directly negatively regulated by
Process(P2) is directly negatively regulated by process(P1) iff: P1 negatively regulates P2 via direct physical interaction between an agent executing P1 (or some part of P1) and an agent executing P2 (or some part of P2). For example, if protein A has protein binding activity(P1) that targets protein B and this binding negatively regulates the kinase activity (P2) of protein B then P2 directly negatively regulated by P1.
GOC:dos
Process(P2) is directly postively regulated by process(P1) iff: P1 positively regulates P2 via direct physical interaction between an agent executing P1 (or some part of P1) and an agent executing P2 (or some part of P2). For example, if protein A has protein binding activity(P1) that targets protein B and this binding positively regulates the kinase activity (P2) of protein B then P2 is directly postively regulated by P1.
dos
2017-09-17T13:52:47Z
directly positively regulated by
Process(P2) is directly postively regulated by process(P1) iff: P1 positively regulates P2 via direct physical interaction between an agent executing P1 (or some part of P1) and an agent executing P2 (or some part of P2). For example, if protein A has protein binding activity(P1) that targets protein B and this binding positively regulates the kinase activity (P2) of protein B then P2 is directly postively regulated by P1.
GOC:dos
David Osumi-Sutherland
X ends_after Y iff: end(Y) before_or_simultaneous_with end(X)
ends after
David Osumi-Sutherland
starts_at_end_of
X immediately_preceded_by Y iff: end(X) simultaneous_with start(Y)
immediately preceded by
David Osumi-Sutherland
ends_at_start_of
meets
X immediately_precedes_Y iff: end(X) simultaneous_with start(Y)
immediately precedes
x overlaps y if and only if there exists some z such that x has part z and z part of y
http://purl.obolibrary.org/obo/BFO_0000051 some (http://purl.obolibrary.org/obo/BFO_0000050 some ?Y)
overlaps
process(P1) regulates process(P2) iff: P1 results in the initiation or termination of P2 OR affects the frequency of its initiation or termination OR affects the magnitude or rate of output of P2.
We use 'regulates' here to specifically imply control. However, many colloquial usages of the term correctly correspond to the weaker relation of 'causally upstream of or within' (aka influences). Consider relabeling to make things more explicit
Chris Mungall
David Hill
Tanya Berardini
GO
Regulation precludes parthood; the regulatory process may not be within the regulated process.
regulates (processual)
false
regulates
Process(P1) negatively regulates process(P2) iff: P1 terminates P2, or P1 descreases the the frequency of initiation of P2 or the magnitude or rate of output of P2.
Chris Mungall
negatively regulates (process to process)
negatively regulates
Process(P1) postively regulates process(P2) iff: P1 initiates P2, or P1 increases the the frequency of initiation of P2 or the magnitude or rate of output of P2.
Chris Mungall
positively regulates (process to process)
positively regulates
mechanosensory neuron capable of detection of mechanical stimulus involved in sensory perception (GO:0050974)
osteoclast SubClassOf 'capable of' some 'bone resorption'
A relation between a material entity (such as a cell) and a process, in which the material entity has the ability to carry out the process.
Chris Mungall
has function realized in
For compatibility with BFO, this relation has a shortcut definition in which the expression "capable of some P" expands to "bearer_of (some realized_by only P)".
capable of
c stands in this relationship to p if and only if there exists some p' such that c is capable_of p', and p' is part_of p.
Chris Mungall
has function in
capable of part of
Chris Mungall
Do not use this relation directly. It is ended as a grouping for relations between occurrents involving the relative timing of their starts and ends.
https://docs.google.com/document/d/1kBv1ep_9g3sTR-SD3jqzFqhuwo9TPNF-l-9fUDbO6rM/edit?pli=1
A relation that holds between two occurrents. This is a grouping relation that collects together all the Allen relations.
temporally related to
p has input c iff: p is a process, c is a material entity, c is a participant in p, c is present at the start of p, and the state of c is modified during p.
Chris Mungall
consumes
has input
A faulty traffic light (material entity) whose malfunctioning (a process) is causally upstream of a traffic collision (a process): the traffic light acts upstream of the collision.
c acts upstream of p if and only if c enables some f that is involved in p' and p' occurs chronologically before p, is not part of p, and affects the execution of p. c is a material entity and f, p, p' are processes.
acts upstream of
A gene product that has some activity, where that activity may be a part of a pathway or upstream of the pathway.
c acts upstream of or within p if c is enables f, and f is causally upstream of or within p. c is a material entity and p is an process.
affects
acts upstream of or within
cjm
holds between x and y if and only if x is causally upstream of y and the progression of x increases the frequency, rate or extent of y
causally upstream of, positive effect
cjm
holds between x and y if and only if x is causally upstream of y and the progression of x decreases the frequency, rate or extent of y
causally upstream of, negative effect
A mereological relationship or a topological relationship
Chris Mungall
Do not use this relation directly. It is ended as a grouping for a diverse set of relations, all involving parthood or connectivity relationships
mereotopologically related to
a particular instances of akt-2 enables some instance of protein kinase activity
Chris Mungall
catalyzes
executes
has
is catalyzing
is executing
This relation differs from the parent relation 'capable of' in that the parent is weaker and only expresses a capability that may not be actually realized, whereas this relation is always realized.
This relation is currently used experimentally by the Gene Ontology Consortium. It may not be stable and may be obsoleted at some future time.
enables
A grouping relationship for any relationship directly involving a function, or that holds because of a function of one of the related entities.
Chris Mungall
This is a grouping relation that collects relations used for the purpose of connecting structure and function
functionally related to
this relation holds between c and p when c is part of some c', and c' is capable of p.
Chris Mungall
false
part of structure that is capable of
c involved_in p if and only if c enables some process p', and p' is part of p
Chris Mungall
actively involved in
enables part of
involved in
inverse of enables
Chris Mungall
enabled by
inverse of regulates
Chris Mungall
regulated by (processual)
regulated by
inverse of negatively regulates
Chris Mungall
negatively regulated by
inverse of positively regulates
Chris Mungall
positively regulated by
inverse of has input
Chris Mungall
input of
inverse of upstream of
Chris Mungall
causally downstream of
Chris Mungall
immediately causally downstream of
This relation groups causal relations between material entities and causal relations between processes
This branch of the ontology deals with causal relations between entities. It is divided into two branches: causal relations between occurrents/processes, and causal relations between material entities. We take an 'activity flow-centric approach', with the former as primary, and define causal relations between material entities in terms of causal relations between occurrents.
To define causal relations in an activity-flow type network, we make use of 3 primitives:
* Temporal: how do the intervals of the two occurrents relate?
* Is the causal relation regulatory?
* Is the influence positive or negative
The first of these can be formalized in terms of the Allen Interval Algebra. Informally, the 3 bins we care about are 'direct', 'indirect' or overlapping. Note that all causal relations should be classified under a RO temporal relation (see the branch under 'temporally related to'). Note that all causal relations are temporal, but not all temporal relations are causal. Two occurrents can be related in time without being causally connected. We take causal influence to be primitive, elucidated as being such that has the upstream changed, some qualities of the donwstream would necessarily be modified.
For the second, we consider a relationship to be regulatory if the system in which the activities occur is capable of altering the relationship to achieve some objective. This could include changing the rate of production of a molecule.
For the third, we consider the effect of the upstream process on the output(s) of the downstream process. If the level of output is increased, or the rate of production of the output is increased, then the direction is increased. Direction can be positive, negative or neutral or capable of either direction. Two positives in succession yield a positive, two negatives in succession yield a positive, otherwise the default assumption is that the net effect is canceled and the influence is neutral.
Each of these 3 primitives can be composed to yield a cross-product of different relation types.
Chris Mungall
Do not use this relation directly. It is intended as a grouping for a diverse set of relations, all involving cause and effect.
causally related to
p is causally upstream of q if and only if p precedes q and p and q are linked in a causal chain
Chris Mungall
causally upstream of
p is immediately causally upstream of q iff both (a) p immediately precedes q and (b) p is causally upstream of q. In addition, the output of p must be an input of q.
Chris Mungall
immediately causally upstream of
p 'causally upstream or within' q iff (1) the end of p is before the end of q and (2) the execution of p exerts some causal influence over the outputs of q; i.e. if p was abolished or the outputs of p were to be modified, this would necessarily affect q.
We would like to make this disjoint with 'preceded by', but this is prohibited in OWL2
Chris Mungall
influences (processual)
affects
causally upstream of or within
inverse of causally upstream of or within
Chris Mungall
causally downstream of or within
c involved in regulation of p if c is involved in some p' and p' regulates some p
Chris Mungall
involved in regulation of
c involved in regulation of p if c is involved in some p' and p' positively regulates some p
Chris Mungall
involved in positive regulation of
c involved in regulation of p if c is involved in some p' and p' negatively regulates some p
Chris Mungall
involved in negative regulation of
c involved in or regulates p if and only if either (i) c is involved in p or (ii) c is involved in regulation of p
OWL does not allow defining object properties via a Union
Chris Mungall
involved in or reguates
involved in or involved in regulation of
A protein that enables activity in a cytosol.
c executes activity in d if and only if c enables p and p occurs_in d. Assuming no action at a distance by gene products, if a gene product enables (is capable of) a process that occurs in some structure, it must have at least some part in that structure.
Chris Mungall
executes activity in
enables activity in
is active in
true
c executes activity in d if and only if c enables p and p occurs_in d. Assuming no action at a distance by gene products, if a gene product enables (is capable of) a process that occurs in some structure, it must have at least some part in that structure.
GOC:cjm
GOC:dos
A relationship that holds between two entities in which the processes executed by the two entities are causally connected.
Considering relabeling as 'pairwise interacts with'
This relation and all sub-relations can be applied to either (1) pairs of entities that are interacting at any moment of time (2) populations or species of entity whose members have the disposition to interact (3) classes whose members have the disposition to interact.
Chris Mungall
Note that this relationship type, and sub-relationship types may be redundant with process terms from other ontologies. For example, the symbiotic relationship hierarchy parallels GO. The relations are provided as a convenient shortcut. Consider using the more expressive processual form to capture your data. In the future, these relations will be linked to their cognate processes through rules.
in pairwise interaction with
interacts with
http://purl.obolibrary.org/obo/MI_0914
https://github.com/oborel/obo-relations/wiki/InteractionRelations
An interaction relationship in which the two partners are molecular entities that directly physically interact with each other for example via a stable binding interaction or a brief interaction during which one modifies the other.
Chris Mungall
binds
molecularly binds with
molecularly interacts with
http://purl.obolibrary.org/obo/MI_0915
Axiomatization to GO to be added later
Chris Mungall
An interaction relation between x and y in which x catalyzes a reaction in which a phosphate group is added to y.
phosphorylates
The entity A, immediately upstream of the entity B, has an activity that regulates an activity performed by B. For example, A and B may be gene products and binding of B by A regulates the kinase activity of B.
A and B can be physically interacting but not necessarily. Immediately upstream means there are no intermediate entity between A and B.
Chris Mungall
Vasundra Touré
molecularly controls
directly regulates activity of
The entity A, immediately upstream of the entity B, has an activity that negatively regulates an activity performed by B.
For example, A and B may be gene products and binding of B by A negatively regulates the kinase activity of B.
Chris Mungall
Vasundra Touré
directly inhibits
molecularly decreases activity of
directly negatively regulates activity of
The entity A, immediately upstream of the entity B, has an activity that positively regulates an activity performed by B.
For example, A and B may be gene products and binding of B by A positively regulates the kinase activity of B.
Chris Mungall
Vasundra Touré
directly activates
molecularly increases activity of
directly positively regulates activity of
Chris Mungall
This property or its subproperties is not to be used directly. These properties exist as helper properties that are used to support OWL reasoning.
helper property (not for use in curation)
p has part that occurs in c if and only if there exists some p1, such that p has_part p1, and p1 occurs in c.
Chris Mungall
has part that occurs in
Chris Mungall
is kinase activity
A relationship between a material entity and a process where the material entity has some causal role that influences the process
causal agent in process
p is causally related to q if and only if p or any part of p and q or any part of q are linked by a chain of events where each event pair is one of direct activation or direct inhibition. p may be upstream, downstream, part of or a container of q.
Chris Mungall
Do not use this relation directly. It is intended as a grouping for a diverse set of relations, all involving cause and effect.
causal relation between processes
The intent is that the process branch of the causal property hierarchy is primary (causal relations hold between occurrents/processes), and that the material branch is defined in terms of the process branch
Chris Mungall
Do not use this relation directly. It is intended as a grouping for a diverse set of relations, all involving cause and effect.
causal relation between entities
Chris Mungall
causally influenced by (entity-centric)
causally influenced by
Chris Mungall
interaction relation helper property
https://github.com/oborel/obo-relations/wiki/InteractionRelations
Chris Mungall
molecular interaction relation helper property
The entity or characteristic A is causally upstream of the entity or characteristic B, A having an effect on B. An entity corresponds to any biological type of entity as long as a mass is measurable. A characteristic corresponds to a particular specificity of an entity (e.g., phenotype, shape, size).
Chris Mungall
Vasundra Touré
causally influences (entity-centric)
causally influences
Process(P1) directly regulates process(P2) iff: P1 regulates P2 via direct physical interaction between an agent executing P1 (or some part of P1) and an agent executing P2 (or some part of P2). For example, if protein A has protein binding activity(P1) that targets protein B and this binding regulates the kinase activity (P2) of protein B then P1 directly regulates P2.
Chris Mungall
directly regulates (processual)
directly regulates
gland SubClassOf 'has part structure that is capable of' some 'secretion by cell'
s 'has part structure that is capable of' p if and only if there exists some part x such that s 'has part' x and x 'capable of' p
Chris Mungall
has part structure that is capable of
A relationship that holds between a material entity and a process in which causality is involved, with either the material entity or some part of the material entity exerting some influence over the process, or the process influencing some aspect of the material entity.
Do not use this relation directly. It is intended as a grouping for a diverse set of relations, all involving cause and effect.
Chris Mungall
causal relation between material entity and a process
pyrethroid -> growth
Holds between c and p if and only if c is capable of some activity a, and a regulates p.
capable of regulating
Holds between c and p if and only if c is capable of some activity a, and a negatively regulates p.
capable of negatively regulating
renin -> arteriolar smooth muscle contraction
Holds between c and p if and only if c is capable of some activity a, and a positively regulates p.
capable of positively regulating
Inverse of 'causal agent in process'
process has causal agent
Process(P1) directly postively regulates process(P2) iff: P1 positively regulates P2 via direct physical interaction between an agent executing P1 (or some part of P1) and an agent executing P2 (or some part of P2). For example, if protein A has protein binding activity(P1) that targets protein B and this binding positively regulates the kinase activity (P2) of protein B then P1 directly positively regulates P2.
directly positively regulates (process to process)
directly positively regulates
Process(P1) directly negatively regulates process(P2) iff: P1 negatively regulates P2 via direct physical interaction between an agent executing P1 (or some part of P1) and an agent executing P2 (or some part of P2). For example, if protein A has protein binding activity(P1) that targets protein B and this binding negatively regulates the kinase activity (P2) of protein B then P1 directly negatively regulates P2.
directly negatively regulates (process to process)
directly negatively regulates
Holds between an entity and an process P where the entity enables some larger compound process, and that larger process has-part P.
cjm
2018-01-25T23:20:13Z
enables subfunction
cjm
2018-01-26T23:49:30Z
acts upstream of or within, positive effect
cjm
2018-01-26T23:49:51Z
acts upstream of or within, negative effect
c 'acts upstream of, positive effect' p if c is enables f, and f is causally upstream of p, and the direction of f is positive
cjm
2018-01-26T23:53:14Z
acts upstream of, positive effect
c 'acts upstream of, negative effect' p if c is enables f, and f is causally upstream of p, and the direction of f is negative
cjm
2018-01-26T23:53:22Z
acts upstream of, negative effect
cjm
2018-03-13T23:55:05Z
causally upstream of or within, negative effect
cjm
2018-03-13T23:55:19Z
causally upstream of or within, positive effect
The entity A has an activity that regulates an activity of the entity B. For example, A and B are gene products where the catalytic activity of A regulates the kinase activity of B.
Vasundra Touré
regulates activity of
q1 decreased_in_magnitude_relative_to q2 if and only if magnitude(q1) < magnitude(q2). Here, magnitude(q) is a function that maps a quality to a unit-invariant scale.
quality
decreased_in_magnitude_relative_to
This relation is used to determine the 'directionality' of relative qualities such as 'decreased strength', relative to the parent type, 'strength'.
decreased_in_magnitude_relative_to
q1 decreased_in_magnitude_relative_to q2 if and only if magnitude(q1) < magnitude(q2). Here, magnitude(q) is a function that maps a quality to a unit-invariant scale.
PATOC:CJM
q1 different_in_magnitude_relative_to q2 if and only if magnitude(q1) NOT =~ magnitude(q2). Here, magnitude(q) is a function that maps a quality to a unit-invariant scale.
quality
different_in_magnitude_relative_to
different_in_magnitude_relative_to
q1 different_in_magnitude_relative_to q2 if and only if magnitude(q1) NOT =~ magnitude(q2). Here, magnitude(q) is a function that maps a quality to a unit-invariant scale.
PATOC:CJM
q1 increased_in_magnitude_relative_to q2 if and only if magnitude(q1) > magnitude(q2). Here, magnitude(q) is a function that maps a quality to a unit-invariant scale.
quality
increased_in_magnitude_relative_to
This relation is used to determine the 'directionality' of relative qualities such as 'increased strength', relative to the parent type, 'strength'.
increased_in_magnitude_relative_to
q1 increased_in_magnitude_relative_to q2 if and only if magnitude(q1) > magnitude(q2). Here, magnitude(q) is a function that maps a quality to a unit-invariant scale.
PATOC:CJM
q1 reciprocal_of q2 if and only if : q1 and q2 are relational qualities and a phenotype e q1 e2 mutually implies a phenotype e2 q2 e.
quality
reciprocal_of
There are frequently two ways to state the same thing: we can say 'spermatocyte lacks asters' or 'asters absent from spermatocyte'. In this case the quality is 'lacking all parts of type' - it is a (relational) quality of the spermatocyte, and it is with respect to instances of 'aster'. One of the popular requirements of PATO is that it continue to support 'absent', so we need to relate statements which use this quality to the 'lacking all parts of type' quality.
reciprocal_of
q1 reciprocal_of q2 if and only if : q1 and q2 are relational qualities and a phenotype e q1 e2 mutually implies a phenotype e2 q2 e.
PATOC:CJM
An entity that exists in full at any time in which it exists at all, persists through time while maintaining its identity and has no temporal parts.
continuant
An entity that has temporal parts and that happens, unfolds or develops through time.
occurrent
A continuant that is a bearer of quality and realizable entity entities, in which other entities inhere and which itself cannot inhere in anything.
independent continuant
An occurrent that has temporal proper parts and for some time t, p s-depends_on some material entity at t.
process
A continuant that inheres in or is borne by other entities. Every instance of A requires some specific instance of B which must always be the same.
specifically dependent continuant
An independent continuant that is spatially extended whose identity is independent of that of other entities and can be maintained through time.
material entity
molecular process
molecular_function
catalytic activity
A biological process represents a specific objective that the organism is genetically programmed to achieve. Biological processes are often described by their outcome or ending state, e.g., the biological process of cell division results in the creation of two daughter cells (a divided cell) from a single parent cell. A biological process is accomplished by a particular set of molecular functions carried out by specific gene products (or macromolecular complexes), often in a highly regulated manner and in a particular temporal sequence.
jl
2012-09-19T15:05:24Z
GO:0000004
GO:0007582
GO:0044699
Wikipedia:Biological_process
biological process
physiological process
biological_process
single organism process
single-organism process
GO:0008150
Note that, in addition to forming the root of the biological process ontology, this term is recommended for use for the annotation of gene products whose biological process is unknown. When this term is used for annotation, it indicates that no information was available about the biological process of the gene product annotated as of the date the annotation was made; the evidence code 'no data' (ND), is used to indicate this.
biological_process
A biological process represents a specific objective that the organism is genetically programmed to achieve. Biological processes are often described by their outcome or ending state, e.g., the biological process of cell division results in the creation of two daughter cells (a divided cell) from a single parent cell. A biological process is accomplished by a particular set of molecular functions carried out by specific gene products (or macromolecular complexes), often in a highly regulated manner and in a particular temporal sequence.
GOC:pdt
true
kinase activity
transferase activity
transferase activity, transferring phosphorus-containing groups
A dependent entity that inheres in a bearer by virtue of how the bearer is related to other entities
quality (PATO)
PATO:0000072
quality
PATO:0000001
quality
A dependent entity that inheres in a bearer by virtue of how the bearer is related to other entities
PATOC:GVG
quality
PATO:0000068
TODO: define this or obsolete it and move children somewhere else.
qualitative
A quality inhering in a bearer by virtue of the whether the bearer differs from normal or average.
quality
PATO:0000069
deviation (from_normal)
A quality inhering in a bearer by virtue of the whether the bearer differs from normal or average.
PATOC:GVG
The number of entities of this type that are part of the whole organism.
PATO:0000053
PATO:0000071
PATO:0001169
PATO:0001226
presence or absence in organism
quantitative
quality
count in organism
number
presence
PATO:0000070
This term was originally named "presence". It has been renamed to reduce ambiguity. Consider annotating with the reciprocal relation,PATO:0001555, has_number_of. For example, rather than E=fin ray Q=count in organism C=10, say E=organism Q=has number of E2= fin ray C=10.
amount
The number of entities of this type that are part of the whole organism.
PATOC:GVG
A quality of a single process inhering in a bearer by virtue of the bearer's occurrence per unit time.
quality
PATO:0000161
rate
A quality of a single process inhering in a bearer by virtue of the bearer's occurrence per unit time.
PATOC:melissa
A quality inhering in a bearer by virtue of the bearer's exhibiting no deviation from normal or average.
quality
average
PATO:0000461
normal
A quality inhering in a bearer by virtue of the bearer's exhibiting no deviation from normal or average.
PATOC:GVG
A quality inhering in a bearer by virtue of the bearer's existence.
quality
present in organism
PATO:0000467
present
A quality inhering in a bearer by virtue of the bearer's existence.
PATOC:GVG
An amount which is relatively high.
PATO:0000420
PATO:0000650
increased number
present in greater numbers in organism
supernumerary
quality
accessory
increased
PATO:0000470
increased amount
An amount which is relatively high.
PATOC:GVG
A rate which is relatively low.
slow rate
quality
PATO:0000911
decreased rate
A rate which is relatively low.
PATO:GVG
A rate which is relatively high.
fast rate
high rate
quality
PATO:0000912
increased rate
A rate which is relatively high.
PATO:GVG
A quality of a physical entity that exists through action of continuants at the physical level of organisation in relation to other entities.
PATO:0002079
Wikipedia:Physical_property
relational physical quality
quality
PATO:0001018
physical quality
A quality of a physical entity that exists through action of continuants at the physical level of organisation in relation to other entities.
PATOC:GVG
A physical quality which inheres in a bearer by virtue of some influence is exerted by the bearer's mass per unit size.
quality
density
PATO:0001019
mass density
A physical quality which inheres in a bearer by virtue of some influence is exerted by the bearer's mass per unit size.
WordNet:WordNet
A physical quality which inheres in a bearer by virtue of the bearer's exhibiting density.
quality
PATO:0001164
dense
A physical quality which inheres in a bearer by virtue of the bearer's exhibiting density.
PATOC:GVG
A quality which inheres in an process.
PATO:0001239
PATO:0001240
quality of a process
quality of occurrent
quality of process
relational quality of occurrent
quality
PATO:0001236
See comments of relational quality of a physical entity.
process quality
A quality which inheres in an process.
PATOC:GVG
A quality which inheres in a continuant.
PATO:0001237
PATO:0001238
snap:Quality
monadic quality of a continuant
multiply inhering quality of a physical entity
quality of a continuant
quality of a single physical entity
quality of an object
quality of continuant
monadic quality of an object
monadic quality of continuant
quality
PATO:0001241
Relational qualities are qualities that hold between multiple entities. Normal (monadic) qualities such as the shape of a eyeball exist purely as a quality of that eyeball. A relational quality such as sensitivity to light is a quality of that eyeball (and connecting nervous system) as it relates to incoming light waves/particles.
physical object quality
A quality which inheres in a continuant.
PATOC:GVG
A biological sex quality inhering in a population of multiple sexes.
quality
PATO:0001338
For example a mixture of females and male or males and hermaphrodites.
mixed sex
A biological sex quality inhering in a population of multiple sexes.
MGED:MGED
A quality inhering in a population by virtue of the proportion of its members that are ill at a given time.
quality
PATO:0001415
morbidity
A quality inhering in a population by virtue of the proportion of its members that are ill at a given time.
PATOC:GVG
The number of parts of a particular type that the bearer entity has. This is a relational quality, and thus holds between two entities: the bearer of the quality, and the type of parts.
OBO_REL:has_part
extra or missing physical or functional parts
has or lacks parts of type
mereological quality
number of
quality
cardinality
number
PATO:0001555
has number of
The number of parts of a particular type that the bearer entity has. This is a relational quality, and thus holds between two entities: the bearer of the quality, and the type of parts.
PATOC:CJM
A density which is higher relative to the normal or average.
high density
quality
PATO:0001788
increased mass density
A density which is higher relative to the normal or average.
PATOC:GVG
A density which is lower relative to the normal or average.
low density
quality
PATO:0001790
decreased mass density
A density which is lower relative to the normal or average.
PATOC:GVG
An amount which is relatively low.
PATO:0000419
PATO:0000468
decreased number
present in fewer numbers in organism
quality
decreased
reduced
subnumerary
PATO:0001997
decreased amount
An amount which is relatively low.
PATOC:GVG
A quality that inheres in an entire population or part of a population.
quality
PATO:0002003
population quality
A quality that inheres in an entire population or part of a population.
PATOC:GVG
george
2009-06-05T09:16:46Z
quality
PATO:0002062
physical quality of a process
A quality that has a value that is increased compared to normal or average.
George Gkoutos
2011-06-16T06:39:43Z
quality
PATO:0002300
increased quality
A quality that has a value that is increased compared to normal or average.
PATOC:GVG
A quality that has a value that is decreased compared to normal or average.
George Gkoutos
2011-06-16T06:40:15Z
quality
PATO:0002301
decreased quality
A quality that has a value that is decreased compared to normal or average.
PATOC:GVG
A quality of a process that has a value that is decreased compared to normal or average.
George Gkoutos
2011-06-16T06:50:59Z
quality
PATO:0002302
decreased process quality
A quality of a process that has a value that is decreased compared to normal or average.
PATOC:GVG
A quality of an object that has a value that is decreased compared to normal or average.
George Gkoutos
2011-06-16T06:51:54Z
quality
PATO:0002303
decreased object quality
A quality of an object that has a value that is decreased compared to normal or average.
PATOC:GVG
A quality of a process that has a value that is increased compared to normal or average.
George Gkoutos
2011-06-16T06:53:08Z
quality
PATO:0002304
increased process quality
A quality of a process that has a value that is increased compared to normal or average.
PATOC:GVG
A quality of an object that has a value that is increased compared to normal or average.
George Gkoutos
2011-06-16T06:54:01Z
quality
PATO:0002305
increased object quality
A quality of an object that has a value that is increased compared to normal or average.
PATOC:GVG
true
MF(X)-directly_regulates->MF(Y)-enabled_by->GP(Z) => MF(Y)-has_input->GP(Y) e.g. if 'protein kinase activity'(X) directly_regulates 'protein binding activity (Y)and this is enabled by GP(Z) then X has_input Z
infer input from direct reg
'causally downstream of' and 'overlaps' should be disjoint properties (a SWRL rule is required because these are non-simple properties).
'causally upstream of' and 'overlaps' should be disjoint properties (a SWRL rule is required because these are non-simple properties).