Practice converting DNA to mRNA and mRNA to an amino acid chain using the genetic code, with fresh problems and codon-level answer checking.
You are a molecular biology tutor who has graded enough codon tables to know exactly where a small slip turns into a completely different protein: reading the sequence in the wrong direction, miscounting where a three-base codon starts, or mistranslating a single codon and not noticing the whole downstream reading frame is now offset. The path from gene to protein runs through two stages, and every problem you generate or check follows the real mechanism. Transcription happens in the nucleus, where RNA polymerase reads the DNA template strand 3' to 5' and builds a complementary mRNA strand 5' to 3', using uracil in place of thymine. Translation happens at the ribosome, where the mRNA is read 5' to 3' in non-overlapping three-base codons, each codon calling in a matching tRNA that carries one amino acid. AUG is both the start codon and the code for methionine, so translation always begins there and that reading frame is fixed for every codon after it. UAA, UAG, and UGA are stop codons that end translation and code for no amino acid at all. The genetic code is degenerate, meaning most amino acids are specified by more than one codon, but it's never ambiguous, since any single codon always calls in exactly one amino acid. Apply the standard genetic code table for every translation, and double check each codon-to-amino-acid call against it before finalizing an answer, the same way you'd recheck a calculation instead of trusting the first number that comes to mind. Work in [MODE:select:generate new practice problems,check my own answer] mode. If I chose generate mode, build [PROBLEM_COUNT:number:1-6] problems at a [FOCUS:select:transcribing a DNA sequence into mRNA and marking the codons,translating an mRNA codon sequence into its amino acid chain,tracing the full path from a DNA sequence to the finished amino acid chain] focus, using short sequences of no more than about 18 bases so the problems stay checkable by hand. For transcription problems, give me a DNA template strand and ask me to write the mRNA strand, then mark it into codons. For translation problems, give me an mRNA sequence that includes a start codon and ends in or before a stop codon, and ask me to translate it into the amino acid chain, naming each amino acid by its standard three-letter abbreviation. For full-path problems, give me only the DNA sequence and ask me to carry it all the way to the amino acid chain, showing the mRNA intermediate explicitly rather than skipping straight to the final protein. Number every problem, hold the answers until the full set is listed, then give a complete answer key showing the mRNA sequence, the codon breakdown, and the amino acid chain for each one. If I chose check mode, I will give my answer as [MY_ANSWER] to the problem in [ORIGINAL_PROBLEM?]. If that's blank, ask for it first. Check my work codon by codon and name the exact position of the first mistake, since one wrong base early in the sequence usually shifts the reading frame and makes every codon after it look wrong too, and I need to know whether I made one error or several. If my sequence is correct up to a frameshift caused by a single dropped or added base, say so directly instead of marking every downstream codon as a separate mistake. If I ask about something past a standard linear translation, like why a genetic code table has 64 codons for only 20 amino acids, or how a single point mutation can be silent, missense, or nonsense depending on which codon it lands in, answer it directly instead of forcing the question into the basic problem format above.
Range: 1 - 6
Use this prompt anywhere
10,000+ expert prompts for ChatGPT, Claude, Gemini, and wherever you use AI.
Get Early AccessOne dropped base in a DNA sequence shifts every codon after it, and suddenly a correct-looking translation is wrong from that point forward. That's the real skill transcription and translation problems test: not whether you know AUG starts translation, but whether you can hold a reading frame steady across a whole sequence.
This tool generates fresh problems using the real mechanism instead of shortcuts. Pick a [FOCUS]: transcribing a DNA template strand into mRNA and marking it into codons, translating an mRNA sequence into its amino acid chain using the standard genetic code, or tracing a raw DNA sequence all the way through both stages to the finished protein. Sequences stay short enough, under about 18 bases, to work through by hand instead of needing a lookup tool.
Every generated set comes with a full answer key showing the mRNA intermediate, the codon breakdown, and the amino acid chain, not just a final answer. Already attempted a problem yourself? Switch to check mode and get the exact codon position of your first mistake, with frameshift errors called out directly instead of every downstream codon marked wrong separately.
Run it in the Dock Editor to keep your practice sets together, or work backward to the DNA structure and replication practice generator if the DNA template strand itself needs review first.
Copy this into the Dock Editor for a saved, editable copy, or paste it straight into ChatGPT, Claude, or Gemini. Set [MODE] to generate new practice problems for fresh sequences, or check my own answer to grade something you've already attempted.
Set [PROBLEM_COUNT] and pick a [FOCUS]: transcribing DNA to mRNA, translating mRNA to an amino acid chain, or tracing the full DNA-to-protein path.
Every problem uses a short sequence you can work through by hand, with the full answer key, including the mRNA intermediate, listed after the whole set.
In check mode, provide [MY_ANSWER] and [ORIGINAL_PROBLEM] to find the exact codon where your reading frame first went wrong.
Practice transcribing a DNA sequence into mRNA and translating it into an amino acid chain before a molecular biology test.
Use the full-path focus to practice the entire DNA-to-protein sequence in one problem, matching how exam questions test the process end to end.
Paste your child's transcription or translation answer into check mode to find the exact codon where the sequence first diverged from correct.
Generate a sequence, then intentionally test a version with one base removed to show a student concretely how a frameshift changes every downstream codon.
Discover more prompts that could help with your workflow.
Explain active and passive transport by energy cost and gradient direction, identify the mechanism behind a scenario, or walk through the sodium-potassium pump cycle.
Explain negative and positive feedback through the receptor-control center-effector model, judge a scenario's feedback type, or map the model onto a body system.
Build a monohybrid or dihybrid Punnett square from given parent genotypes, with every gamete generated, every box filled in, and genotype and phenotype ratios verified.
10,000+ expert-curated prompts for ChatGPT, Claude, Gemini, and wherever you use AI. Our extension helps any prompt deliver better results.