A guide to choosing fluorescent proteins (2024)

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See Also
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A guide to choosing fluorescent proteins (2024)

FAQs

Which fluorescent protein should I use? ›

For single-color experiments, green FPs are the most common choice. EGFP is the most popular green FP and is a good choice for many single-color studies. However, other green FPs, such as TurboGFP (a.k.a. maxGFP), may be better choices for certain applications.

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Is DsRed the same as RFP? ›

While DsRed is a specific type of RFP, the term RFP encompasses a wider range of red fluorescent proteins, including DsRed. Advances in genetic engineering have led to the development of numerous RFP variants with improved properties for various research and industrial applications.

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What are the most commonly used fluorescent proteins? ›

Green fluorescent protein (GFP) from jellyfish Aequorea victoria is the most extensively studied and widely used in cell biology protein. GFP-like proteins constitute a fast growing family as several naturally occurring GFP-like proteins have been discovered and enhanced mutants of Aequorea GFP have been created.

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What is the difference between mCherry and RFP? ›

mCherry is a red fluorescent protein (RFP), classified as a luminescent protein, that belongs to a group of fluorescent protein chromophores. mCherry is a part of the mFruits protein family, which is a family of mRFPs, monomeric red fluorescent proteins.

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How do I choose fluorochromes? ›

Choose the brightest fluorochrome for your least expressed protein and the dimmest fluoro- chrome for your most highly expressed protein. (View our Expression of Common Cell Surface Proteins chart to assist you.) Generally, on leukocytes, CD45 is one of the most highly ex- pressed cell surface proteins.

What is the smallest brightest fluorescent protein? ›

With molecular weight of only 17 kDa, miRFP670nano is the smallest monomeric NIR FP that fluoresces in mammalian cells as bright as twice bigger state-of-art two-domain NIR FPs.

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What is the difference between GFP and enhanced green fluorescent protein? ›

The difference between the fluorescence of the green fluorescent protein (GFP) and the enhanced green fluorescent protein (EGFP) is that EGFP emits 35× the fluorescence of GFP when excited with ultraviolet or blue light: it is much brighter.

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What are the disadvantages of mCherry? ›

mCherry is a very popular red fluorescent protein. However it has several disadvantages: It is shifted towards far red (ex peak 585 nm) so it often is not imaged optimally with the illumination sources and filters commonly available. It bleaches fast.

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Can you use GFP and RFP together? ›

Red fluorescent proteins (RFPs) combined with GFP are attractive probes for double-fluorescence labeling of proteins in live cells.

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Can you use GFP and mCherry together? ›

Due to the spectral properties of GFP and mCherry, they are considered an ideal combination for co-localisation and co-expression experiments.

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What is the difference between Venus and EGFP? ›

The Venus protein differs from EGFP and EYFP by 8 and 5 amino acid exchang- es, respectively. It has the same spectral properties as EYFP, but it has a 30-fold higher relative fluorescence, it matures faster and is less sensitive to pH and chloride ion concentrations (7).

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Is neon green better than GFP? ›

The monomeric GFP mNeonGreen is about 3- to 5-times brighter than GFP and monomeric enhanced GFP and shows high photostability. The maturation half-time of mNeonGreen is about 3-fold faster than that of monomeric enhanced GFP.

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What is the difference between EGFP and mGFP? ›

Compared to EGFP, mGFP provides about the same brightness of fluorescence but is significantly more pH stable. mGFP is specially optimized for expression at 37°C.