Toolkit/genetically engineered biosensors

genetically engineered biosensors

Construct Pattern·Research·Since 2021

Also known as: biosensors

Taxonomy: Mechanism Branch / Architecture. Workflows sit above the mechanism and technique branches rather than replacing them.

Summary

Elucidation of the spatiotemporal nature of the hormone network can be accomplished by using genetically engineered biosensors.

Usefulness & Problems

Why this is useful

Genetically engineered biosensors are used to report the distribution and concentration of plant hormones in planta. The abstract states that they enable elucidation of the spatiotemporal nature of hormone networks.; determining the distribution of plant hormones in planta; determining the concentration of plant hormones in planta; non-invasive reporting of hormones in plants; studying spatiotemporal hormone networks

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Genetically engineered biosensors are used to report the distribution and concentration of plant hormones in planta. The abstract states that they enable elucidation of the spatiotemporal nature of hormone networks.

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determining the distribution of plant hormones in planta

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determining the concentration of plant hormones in planta

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non-invasive reporting of hormones in plants

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studying spatiotemporal hormone networks

Problem solved

They address the need to measure plant hormone distribution and concentration with high sensitivity and in a non-invasive manner under different conditions.; reports hormone distribution and concentration in planta with high sensitivity and in a non-invasive manner

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They address the need to measure plant hormone distribution and concentration with high sensitivity and in a non-invasive manner under different conditions.

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reports hormone distribution and concentration in planta with high sensitivity and in a non-invasive manner

Problem links

reports hormone distribution and concentration in planta with high sensitivity and in a non-invasive manner

Literature

They address the need to measure plant hormone distribution and concentration with high sensitivity and in a non-invasive manner under different conditions.

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They address the need to measure plant hormone distribution and concentration with high sensitivity and in a non-invasive manner under different conditions.

Taxonomy & Function

Primary hierarchy

Mechanism Branch

Architecture: A reusable architecture pattern for arranging parts into an engineered system.

Techniques

No technique tags yet.

Target processes

transcription

Implementation Constraints

cofactor dependency: cofactor requirement unknownencoding mode: genetically encodedimplementation constraint: context specific validationoperating role: sensor

These approaches require genetically engineered biosensor constructs in plants. The abstract further states that reported sensor designs are based on fluorescence of transcriptional reporters, degron-based sensors, or receptor-based sensors.; requires genetically engineered biosensor systems in plants

Independent follow-up evidence is still limited. Validation breadth across biological contexts is still narrow. Independent reuse still looks limited, so the evidence base may be fragile. No canonical validation observations are stored yet, so context-specific performance remains under-specified.

Validation

Cell-freeBacteriaMammalianMouseHumanTherapeuticIndep. Replication

Supporting Sources

Ranked Claims

Claim 1tool capabilitysupports2021Source 1needs review

Genetically engineered biosensors can be used to elucidate the spatiotemporal nature of plant hormone networks by determining hormone distribution and concentration in planta with high sensitivity and in a non-invasive manner.

Claim 2tool designsupports2021Source 1needs review

Plant hormone biosensors described in this field are based on fluorescence of transcriptional reporters, degron-based sensors, or receptor-based sensors.

Approval Evidence

1 source2 linked approval claimsfirst-pass slug genetically-engineered-biosensors
Elucidation of the spatiotemporal nature of the hormone network can be accomplished by using genetically engineered biosensors.

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tool capabilitysupports

Genetically engineered biosensors can be used to elucidate the spatiotemporal nature of plant hormone networks by determining hormone distribution and concentration in planta with high sensitivity and in a non-invasive manner.

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tool designsupports

Plant hormone biosensors described in this field are based on fluorescence of transcriptional reporters, degron-based sensors, or receptor-based sensors.

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Comparisons

Source-stated alternatives

The abstract contrasts three biosensor design bases within this area: fluorescence of transcriptional reporters, degron-based sensors, and receptor-based sensors.

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The abstract contrasts three biosensor design bases within this area: fluorescence of transcriptional reporters, degron-based sensors, and receptor-based sensors.

Source-backed strengths

described as high sensitivity; described as non-invasive; supports spatiotemporal analysis of hormone networks

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described as high sensitivity

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described as non-invasive

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supports spatiotemporal analysis of hormone networks

Compared with degron-based sensors

The abstract contrasts three biosensor design bases within this area: fluorescence of transcriptional reporters, degron-based sensors, and receptor-based sensors.

Shared frame: source-stated alternative in extracted literature

Strengths here: described as high sensitivity; described as non-invasive; supports spatiotemporal analysis of hormone networks.

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The abstract contrasts three biosensor design bases within this area: fluorescence of transcriptional reporters, degron-based sensors, and receptor-based sensors.

Compared with fluorescence transcriptional reporters

The abstract contrasts three biosensor design bases within this area: fluorescence of transcriptional reporters, degron-based sensors, and receptor-based sensors.

Shared frame: source-stated alternative in extracted literature

Strengths here: described as high sensitivity; described as non-invasive; supports spatiotemporal analysis of hormone networks.

Source:

The abstract contrasts three biosensor design bases within this area: fluorescence of transcriptional reporters, degron-based sensors, and receptor-based sensors.

Compared with receptor-based sensors

The abstract contrasts three biosensor design bases within this area: fluorescence of transcriptional reporters, degron-based sensors, and receptor-based sensors.

Shared frame: source-stated alternative in extracted literature

Strengths here: described as high sensitivity; described as non-invasive; supports spatiotemporal analysis of hormone networks.

Source:

The abstract contrasts three biosensor design bases within this area: fluorescence of transcriptional reporters, degron-based sensors, and receptor-based sensors.

Ranked Citations

  1. 1.
    StructuralSource 1The Plant Journal2021Claim 1Claim 2

    Extracted from this source document.