In automated DNA sequencing systems based on dye terminator chemistry, how are the four nucleotide bases (A, C, G, T) distinguished during detection?

Introduction / Context:
Modern capillary and next generation Sanger based sequencing platforms identify nucleotides by fluorescent signals. Understanding how each base is differentiated is fundamental for interpreting chromatograms and troubleshooting runs in molecular diagnostics and genomics labs.

Given Data / Assumptions:

• Automated sequencing relies on labeled nucleotides or terminators.
• A detector measures signals as fragments migrate past a window.
• The platform is not using radiolabels or immuno tags.

Concept / Approach:
In dye terminator sequencing, each dideoxynucleotide terminator (ddATP, ddCTP, ddGTP, ddTTP) carries a spectrally distinct fluorescent dye. As terminated fragments are separated by size in a capillary, a laser excites the dyes and an optical system records emission wavelengths. The instrument software assigns base calls based on the unique fluorescent signature of each dye.

Step-by-Step Solution:
Recognize that Sanger automation uses fluorescently labeled terminators. Note that each base must have a unique detectable signature. Match this requirement to the use of distinct fluorophores. Select distinctive fluorescent tag as the correct mechanism.

Verification / Alternative check:
Chromatogram peaks appear in different colors corresponding to A, C, G, and T; spectral deconvolution confirms dye specific identification.

Why Other Options Are Wrong:

• Different radioactive tag: older manual methods used radioactivity, not automated multi color detection.
• Cytosine at start: irrelevant to base differentiation.
• Unique antibody: antibodies are not used for base discrimination in sequencing ladders.

Common Pitfalls:
Confusing dye primer with dye terminator approaches; both rely on fluorescent tags, not antibodies or radioactivity in current automated systems.

Final Answer:
distinctive fluorescent tag