ReddRadar
Agent skill
bio-primer-design-primer-basics
Install this agent skill to your Project
npx add-skill https://github.com/FreedomIntelligence/OpenClaw-Medical-Skills/tree/main/skills/bio-primer-design-primer-basics
SKILL.md
name: bio-primer-design-primer-basics description: Design PCR primers for a target sequence using primer3-py. Specify target regions, product size, melting temperature, and other constraints. Returns ranked primer pairs with quality metrics. Use when designing standard PCR primers. tool_type: python primary_tool: primer3-py measurable_outcome: Execute skill workflow successfully with valid output within 15 minutes. allowed-tools:
- read_file
- run_shell_command
PCR Primer Design
Design PCR primers using primer3-py, the Python binding for Primer3.
Required Imports
import primer3
from primer3 import p3helpers
from Bio import SeqIO
from Bio.Seq import Seq
Sequence Preparation (p3helpers)
# Sanitize sequence (uppercase, remove whitespace)
raw_seq = ' atgc gatc GATC '
clean_seq = p3helpers.sanitize_sequence(raw_seq)
print(f'Cleaned: {clean_seq}') # 'ATGCGATCGATC'
# Reverse complement for designing reverse primers
seq = 'ATGCGATCGATC'
rc_seq = p3helpers.reverse_complement(seq)
print(f'Reverse complement: {rc_seq}') # 'GATCGATCGCAT'
# Ensure valid DNA sequence (ACGT only, uppercase)
valid_seq = p3helpers.ensure_acgt_uppercase('atgcNNgatc') # Raises error if invalid
Basic Primer Design
sequence = 'ATGCGTACGATCGATCGATCGATCGATCGATCGATCGATCGATCGATCGATCGATCGATCGATCG'
result = primer3.design_primers(
seq_args={'SEQUENCE_TEMPLATE': sequence},
global_args={
'PRIMER_PRODUCT_SIZE_RANGE': [[100, 300]],
'PRIMER_MIN_TM': 57.0,
'PRIMER_OPT_TM': 60.0,
'PRIMER_MAX_TM': 63.0,
'PRIMER_MIN_GC': 40.0,
'PRIMER_MAX_GC': 60.0,
}
)
Extract Primer Results
num_returned = result['PRIMER_PAIR_NUM_RETURNED']
print(f'Found {num_returned} primer pairs')
for i in range(num_returned):
left = result[f'PRIMER_LEFT_{i}_SEQUENCE']
right = result[f'PRIMER_RIGHT_{i}_SEQUENCE']
left_tm = result[f'PRIMER_LEFT_{i}_TM']
right_tm = result[f'PRIMER_RIGHT_{i}_TM']
product_size = result[f'PRIMER_PAIR_{i}_PRODUCT_SIZE']
print(f'Pair {i}: {left} / {right}')
print(f' Tm: {left_tm:.1f}C / {right_tm:.1f}C, Product: {product_size}bp')
Target a Specific Region
# Target a specific region: [start, length]
result = primer3.design_primers(
seq_args={
'SEQUENCE_TEMPLATE': sequence,
'SEQUENCE_TARGET': [100, 50], # Target region at position 100, length 50
},
global_args={
'PRIMER_PRODUCT_SIZE_RANGE': [[150, 300]],
'PRIMER_OPT_TM': 60.0,
}
)
Primers Must Span a Region
# Primers must span this region (e.g., exon junction)
result = primer3.design_primers(
seq_args={
'SEQUENCE_TEMPLATE': sequence,
'SEQUENCE_INCLUDED_REGION': [50, 200], # Primers within this region
},
global_args={'PRIMER_PRODUCT_SIZE_RANGE': [[100, 250]]}
)
Exclude Regions
# Exclude regions (e.g., SNP positions, repeats)
result = primer3.design_primers(
seq_args={
'SEQUENCE_TEMPLATE': sequence,
'SEQUENCE_EXCLUDED_REGION': [[150, 20], [300, 15]], # Regions to avoid
},
global_args={'PRIMER_PRODUCT_SIZE_RANGE': [[100, 300]]}
)
Constrain Primer Positions
# Force primer to overlap a specific position
result = primer3.design_primers(
seq_args={
'SEQUENCE_TEMPLATE': sequence,
'SEQUENCE_FORCE_LEFT_START': 50, # Left primer must start here
'SEQUENCE_FORCE_RIGHT_START': 250, # Right primer must start here
},
global_args={'PRIMER_PRODUCT_SIZE_RANGE': [[150, 250]]}
)
Design for Sequencing
# Single primer for sequencing
result = primer3.design_primers(
seq_args={'SEQUENCE_TEMPLATE': sequence},
global_args={
'PRIMER_PICK_LEFT_PRIMER': 1,
'PRIMER_PICK_RIGHT_PRIMER': 0, # Only design left primer
'PRIMER_PICK_INTERNAL_OLIGO': 0,
'PRIMER_OPT_SIZE': 20,
'PRIMER_MIN_SIZE': 18,
'PRIMER_MAX_SIZE': 25,
}
)
Full Parameter Control
result = primer3.design_primers(
seq_args={
'SEQUENCE_TEMPLATE': sequence,
'SEQUENCE_TARGET': [200, 50],
},
global_args={
'PRIMER_PRODUCT_SIZE_RANGE': [[150, 300], [300, 500]], # Multiple ranges
'PRIMER_NUM_RETURN': 5,
'PRIMER_MIN_SIZE': 18,
'PRIMER_OPT_SIZE': 20,
'PRIMER_MAX_SIZE': 25,
'PRIMER_MIN_TM': 57.0,
'PRIMER_OPT_TM': 60.0,
'PRIMER_MAX_TM': 63.0,
'PRIMER_MIN_GC': 40.0,
'PRIMER_OPT_GC_PERCENT': 50.0,
'PRIMER_MAX_GC': 60.0,
'PRIMER_MAX_POLY_X': 4, # Max consecutive identical bases
'PRIMER_MAX_NS_ACCEPTED': 0, # No ambiguous bases
'PRIMER_MAX_SELF_ANY': 8, # Self-complementarity
'PRIMER_MAX_SELF_END': 3, # 3' self-complementarity
'PRIMER_PAIR_MAX_COMPL_ANY': 8, # Pair complementarity
'PRIMER_PAIR_MAX_COMPL_END': 3, # Pair 3' complementarity
'PRIMER_MAX_END_STABILITY': 9.0, # Max 3' end stability (delta G)
}
)
Load Sequence from FASTA
from Bio import SeqIO
record = SeqIO.read('gene.fasta', 'fasta')
sequence = str(record.seq)
result = primer3.design_primers(
seq_args={'SEQUENCE_TEMPLATE': sequence, 'SEQUENCE_ID': record.id},
global_args={'PRIMER_PRODUCT_SIZE_RANGE': [[100, 300]], 'PRIMER_OPT_TM': 60.0}
)
Calculate Tm Directly
# Calculate Tm for an existing primer
tm = primer3.calc_tm('ATGCGATCGATCGATCGATC')
print(f'Tm: {tm:.1f}C')
# With custom salt/DNA concentrations
tm = primer3.calc_tm('ATGCGATCGATCGATCGATC', mv_conc=50.0, dv_conc=1.5, dntp_conc=0.2, dna_conc=50.0)
Tm Calculation Defaults
| Parameter | Default | Description |
|---|---|---|
| mv_conc | 50.0 mM | Monovalent cations (Na+, K+) |
| dv_conc | 0.0 mM | Divalent cations (Mg2+) |
| dntp_conc | 0.0 mM | dNTP concentration |
| dna_conc | 50.0 nM | DNA oligo concentration |
Calculate Hairpin and Dimer Tm
# Hairpin Tm
hairpin = primer3.calc_hairpin('ATGCGATCGATCGATCGATC')
print(f'Hairpin Tm: {hairpin.tm:.1f}C, dG: {hairpin.dg:.1f}')
# Homodimer Tm
homodimer = primer3.calc_homodimer('ATGCGATCGATCGATCGATC')
print(f'Homodimer Tm: {homodimer.tm:.1f}C, dG: {homodimer.dg:.1f}')
# Heterodimer Tm (between two different primers)
heterodimer = primer3.calc_heterodimer('ATGCGATCGATCGATCGATC', 'GCTAGCTAGCTAGCTAGCTA')
print(f'Heterodimer Tm: {heterodimer.tm:.1f}C, dG: {heterodimer.dg:.1f}')
Format Results as DataFrame
import pandas as pd
def primers_to_dataframe(result):
rows = []
for i in range(result['PRIMER_PAIR_NUM_RETURNED']):
rows.append({
'pair': i,
'left_seq': result[f'PRIMER_LEFT_{i}_SEQUENCE'],
'right_seq': result[f'PRIMER_RIGHT_{i}_SEQUENCE'],
'left_tm': result[f'PRIMER_LEFT_{i}_TM'],
'right_tm': result[f'PRIMER_RIGHT_{i}_TM'],
'left_gc': result[f'PRIMER_LEFT_{i}_GC_PERCENT'],
'right_gc': result[f'PRIMER_RIGHT_{i}_GC_PERCENT'],
'product_size': result[f'PRIMER_PAIR_{i}_PRODUCT_SIZE'],
'penalty': result[f'PRIMER_PAIR_{i}_PENALTY'],
})
return pd.DataFrame(rows)
df = primers_to_dataframe(result)
print(df)
Common Global Arguments
| Parameter | Description | Default |
|---|---|---|
| PRIMER_PRODUCT_SIZE_RANGE | Allowed product sizes | [[100,300]] |
| PRIMER_NUM_RETURN | Number of primer pairs | 5 |
| PRIMER_MIN/OPT/MAX_SIZE | Primer length | 18/20/27 |
| PRIMER_MIN/OPT/MAX_TM | Melting temperature | 57/60/63 |
| PRIMER_MIN/MAX_GC | GC content percent | 20/80 |
| PRIMER_MAX_POLY_X | Max poly-X run | 5 |
| PRIMER_MAX_SELF_ANY | Self complementarity | 8 |
| PRIMER_MAX_SELF_END | 3' self complementarity | 3 |
Related Skills
- qpcr-primers - Design primers with internal probes for qPCR
- primer-validation - Check primers for specificity and secondary structures
- sequence-io - Load template sequences
- database-access/local-blast - BLAST primers for specificity checking
Recommended Agent Skills
Expand your agent's capabilities with these related and highly-rated skills.
FreedomIntelligence/OpenClaw-Medical-Skills
vcf-annotator
Annotate VCF variants with VEP, ClinVar, gnomAD frequencies, and ancestry-aware context. Generates prioritised variant reports.
FreedomIntelligence/OpenClaw-Medical-Skills
chemist-analyst
Analyzes events through chemistry lens using molecular structure, reaction mechanisms, thermodynamics, kinetics, and analytical techniques (spectroscopy, chromatography, mass spectrometry). Provides insights on chemical processes, material properties, reaction pathways, synthesis, and analytical methods. Use when: Chemical reactions, material analysis, synthesis planning, process optimization, environmental chemistry. Evaluates: Molecular structure, reaction mechanisms, yield, selectivity, safety, environmental impact.
FreedomIntelligence/OpenClaw-Medical-Skills
bio-alignment-io
Read, write, and convert multiple sequence alignment files using Biopython Bio.AlignIO. Supports Clustal, PHYLIP, Stockholm, FASTA, Nexus, and other alignment formats for phylogenetics and conservation analysis. Use when reading, writing, or converting alignment file formats.
FreedomIntelligence/OpenClaw-Medical-Skills
sleep-analyzer
分析睡眠数据、识别睡眠模式、评估睡眠质量,并提供个性化睡眠改善建议。支持与其他健康数据的关联分析。
FreedomIntelligence/OpenClaw-Medical-Skills
metabolomics-workbench-database
Access NIH Metabolomics Workbench via REST API (4,200+ studies). Query metabolites, RefMet nomenclature, MS/NMR data, m/z searches, study metadata, for metabolomics and biomarker discovery.
FreedomIntelligence/OpenClaw-Medical-Skills
bio-hi-c-analysis-matrix-operations
Balance, normalize, and transform Hi-C contact matrices using cooler and cooltools. Apply iterative correction (ICE), compute expected values, and generate observed/expected matrices. Use when normalizing or transforming Hi-C matrices.
Didn't find tool you were looking for?