-
Generate the HD46_Ctrol annotation
mamba activate trycycler cd trycycler_HD46_Ctrl; trycycler cluster --threads 55 --assemblies assemblies/*.fasta --reads reads.fastq --out_dir trycycler; trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_001 mv trycycler/cluster_001/1_contigs/J_ctg000010.fasta . mv trycycler/cluster_001/1_contigs/L_tig00000016.fasta . mv trycycler/cluster_001/1_contigs/R_tig00000001.fasta . mv trycycler/cluster_001/1_contigs/H_utg000001c.fasta . trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_002 mv trycycler/cluster_002/1_contigs/*00000*.fasta . Error: unable to find a suitable common sequence trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_003 mv trycycler/cluster_003/1_contigs/F_tig00000004.fasta . mv trycycler/cluster_003/1_contigs/L_tig00000003.fasta . trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_004 mv trycycler/cluster_004/1_contigs/J_ctg000000.fasta . mv trycycler/cluster_004/1_contigs/P_ctg000000.fasta . mv trycycler/cluster_004/1_contigs/S_contig_2.fasta . trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_005 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_006 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_007 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_008 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_009 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_010 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_011 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_012 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_013 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_014 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_015 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_016 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_017 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_018 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_019 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_020 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_021 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_022 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_023 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_024 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_025 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_026 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_027 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_028 trycycler reconcile --threads 55 --reads reads.fastq --cluster_dir trycycler/cluster_029 trycycler msa --threads 55 --cluster_dir trycycler/cluster_001 trycycler msa --threads 55 --cluster_dir trycycler/cluster_004 trycycler partition --threads 55 --reads reads.fastq --cluster_dirs trycycler/cluster_001 trycycler partition --threads 55 --reads reads.fastq --cluster_dirs trycycler/cluster_004 trycycler consensus --threads 55 --cluster_dir trycycler/cluster_001 trycycler consensus --threads 55 --cluster_dir trycycler/cluster_004 #Polish --> TODO: Need to be Debugged! for c in trycycler/cluster_001 trycycler/cluster_004; do medaka_consensus -i "$c"/4_reads.fastq -d "$c"/7_final_consensus.fasta -o "$c"/medaka -m r941_min_sup_g507 -t 12 mv "$c"/medaka/consensus.fasta "$c"/8_medaka.fasta rm -r "$c"/medaka "$c"/*.fai "$c"/*.mmi # clean up done # cat trycycler/cluster_*/8_medaka.fasta > trycycler/consensus.fasta cp trycycler/cluster_001/7_final_consensus.fasta HD46_Ctrl_chr.fasta cp trycycler/cluster_004/7_final_consensus.fasta HD46_Ctrl_plasmid.fasta -
install mambaforge https://conda-forge.org/miniforge/ (recommended)
#download Mambaforge-24.9.2-0-Linux-x86_64.sh from website chmod +x Mambaforge-24.9.2-0-Linux-x86_64.sh ./Mambaforge-24.9.2-0-Linux-x86_64.sh To activate this environment, use: micromamba activate /home/jhuang/mambaforge Or to execute a single command in this environment, use: micromamba run -p /home/jhuang/mambaforge mycommand installation finished. Do you wish to update your shell profile to automatically initialize conda? This will activate conda on startup and change the command prompt when activated. If you'd prefer that conda's base environment not be activated on startup, run the following command when conda is activated: conda config --set auto_activate_base false You can undo this by running `conda init --reverse $SHELL`? [yes|no] [no] >>> yes no change /home/jhuang/mambaforge/condabin/conda no change /home/jhuang/mambaforge/bin/conda no change /home/jhuang/mambaforge/bin/conda-env no change /home/jhuang/mambaforge/bin/activate no change /home/jhuang/mambaforge/bin/deactivate no change /home/jhuang/mambaforge/etc/profile.d/conda.sh no change /home/jhuang/mambaforge/etc/fish/conf.d/conda.fish no change /home/jhuang/mambaforge/shell/condabin/Conda.psm1 no change /home/jhuang/mambaforge/shell/condabin/conda-hook.ps1 no change /home/jhuang/mambaforge/lib/python3.12/site-packages/xontrib/conda.xsh no change /home/jhuang/mambaforge/etc/profile.d/conda.csh modified /home/jhuang/.bashrc ==> For changes to take effect, close and re-open your current shell. <== no change /home/jhuang/mambaforge/condabin/conda no change /home/jhuang/mambaforge/bin/conda no change /home/jhuang/mambaforge/bin/conda-env no change /home/jhuang/mambaforge/bin/activate no change /home/jhuang/mambaforge/bin/deactivate no change /home/jhuang/mambaforge/etc/profile.d/conda.sh no change /home/jhuang/mambaforge/etc/fish/conf.d/conda.fish no change /home/jhuang/mambaforge/shell/condabin/Conda.psm1 no change /home/jhuang/mambaforge/shell/condabin/conda-hook.ps1 no change /home/jhuang/mambaforge/lib/python3.12/site-packages/xontrib/conda.xsh no change /home/jhuang/mambaforge/etc/profile.d/conda.csh no change /home/jhuang/.bashrc No action taken. WARNING conda.common.path.windows:_path_to(100): cygpath is not available, fallback to manual path conversion WARNING conda.common.path.windows:_path_to(100): cygpath is not available, fallback to manual path conversion Added mamba to /home/jhuang/.bashrc ==> For changes to take effect, close and re-open your current shell. <== Thank you for installing Mambaforge! Close your terminal window and open a new one, or run: #source ~/mambaforge/bin/activate conda --version mamba --version https://github.com/conda-forge/miniforge/releases Note * After installation, please make sure that you do not have the Anaconda default channels configured. conda config --show channels conda config --remove channels defaults conda config --add channels conda-forge conda config --show channels conda config --set channel_priority strict #conda clean --all conda config --remove channels biobakery * !!!!Do not install anything into the base environment as this might break your installation. See here for details.!!!! # --Deprecated method: mamba installing on conda-- #conda install -n base --override-channels -c conda-forge mamba 'python_abi=*=*cp*' # * Note that installing mamba into any other environment than base is not supported. # #conda activate base #conda install conda #conda uninstall mamba #conda install mamba
2: install required Tools on the mamba env
* Sniffles2: Detect structural variants, including transposons, from long-read alignments.
* RepeatModeler2: Identify and classify transposons de novo.
* RepeatMasker: Annotate known transposable elements using transposon libraries.
* SVIM: An alternative structural variant caller optimized for long-read sequencing, if needed.
* SURVIVOR: Consolidate structural variants across samples for comparative analysis.
mamba deactivate
# Create a new conda environment
mamba create -n transposon_long python=3.6 -y
# Activate the environment
mamba activate transposon_long
mamba install -c bioconda sniffles
mamba install -c bioconda repeatmodeler repeatmasker
# configure repeatmasker database
mamba info --envs
cd /home/jhuang/mambaforge/envs/transposon_long/share/RepeatMasker
#mamba install python=3.6
mamba install -c bioconda svim
mamba install -c bioconda survivor-
Test the installed tools
# Check versions sniffles --version RepeatModeler -h RepeatMasker -h svim --help SURVIVOR --help mamba install -c conda-forge perl r -
Data Preparation
Raw Signal Data: Nanopore devices generate electrical signal data as DNA passes through the nanopore. Basecalling: Tools like Guppy or Dorado are used to convert raw signals into nucleotide sequences (FASTQ files). -
Preprocessing
Quality Filtering: Remove low-quality reads using tools like Filtlong or NanoFilt. Adapter Trimming: Identify and remove sequencing adapters with tools like Porechop. -
(Optional) Variant Calling for SNP and Indel Detection:
Tools like Medaka, Longshot, or Nanopolish analyze the aligned reads to identify SNPs and small indels. -
(OFFICIAL STARTING POINT) Alignment and Structural Variant Calling: Tools such as Sniffles or SVIM detect large insertions, deletions, and other structural variants. 使用长读长测序工具如 SVIM 或 Sniffles 检测结构变异(e.g. 散在性重复序列)。
#NOTE that the ./batch1_depth25/trycycler_WT/reads.fastq and F24A430001437_BACctmoD/BGI_result/Separate/${sample}/1.Cleandata/${sample}.filtered_reads.fq.gz are the same! # -- PREPARING the input fastq-data, merge the fastqz and move the top-directory # Under raw_data/no_sample_id/20250731_0943_MN45170_FBD12615_97f118c2/fastq_pass zcat ./barcode01/FBD12615_pass_barcode01_97f118c2_aa46ecf7_0.fastq.gz ./barcode01/FBD12615_pass_barcode01_97f118c2_aa46ecf7_1.fastq.gz ./barcode01/FBD12615_pass_barcode01_97f118c2_aa46ecf7_2.fastq.gz ./barcode01/FBD12615_pass_barcode01_97f118c2_aa46ecf7_3.fastq.gz ... | gzip > HD46_1.fastq.gz mv ./raw_data/no_sample_id/20250731_0943_MN45170_FBD12615_97f118c2/fastq_pass/HD46_1.fastq.gz ~/DATA/Data_Patricia_Transposon_2025 #this are the corresponding sample names: #barcode 1: HD46-1 #barcode 2: HD46-2 #barcode 3: HD46-3 #barcode 4: HD46-4 mv barcode01.fastq.gz HD46_1.fastq.gz mv barcode02.fastq.gz HD46_2.fastq.gz mv barcode03.fastq.gz HD46_3.fastq.gz mv barcode04.fastq.gz HD46_4.fastq.gz # -- CALCULATE the coverages #!/bin/bash for bam in barcode*_minimap2.sorted.bam; do echo "Processing $bam ..." avg_cov=$(samtools depth -a "$bam" | awk '{sum+=$3; cnt++} END {if (cnt>0) print sum/cnt; else print 0}') echo -e "${bam}\t${avg_cov}" >> coverage_summary.txt done # ---- !!!! LOGIN the suitable environment !!!! ---- # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! # mamba activate transposon_long # -- TODO: AFTERNOON_DEBUG_THIS: FAILED and not_USED: Alignment and Detect structural variants in each sample using SVIM which used aligner ngmlr or mimimap2 #mamba install -c bioconda ngmlr mamba install -c bioconda svim #SEARCH FOR "HD46_Ctrl_chr_plasmid.fasta" for finding the insertion-calling-commands # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! for all 4 options # # ---- Option_1: minimap2 (aligner) + SVIM (structural variant caller) --> SUCCESSFUL ---- for sample in HD46_1 HD46_2 HD46_3 HD46_4 HD46_5 HD46_6 HD46_7 HD46_8 HD46_13; do #INS,INV,DUP:TANDEM,DUP:INT,BND svim reads --aligner minimap2 --nanopore minimap2+svim_${sample} ${sample}.fastq.gz HD46_Ctrl_chr_plasmid.fasta --cores 20 --types INS --min_sv_size 100 --sequence_allele --insertion_sequences --read_names; done #svim alignment svim_alignment_minmap2_1_re 1.sorted.bam CP020463_.fasta --types INS --sequence_alleles --insertion_sequences --read_names # ---- Option_2: minamap2 (aligner) + Sniffles2 (structural variant caller) --> SUCCESSFUL ---- #Minimap2: A commonly used aligner for nanopore sequencing data. # Align Long Reads to the WT Reference using Minimap2 #sniffles -m WT.sorted.bam -v WT.vcf -s 10 -l 50 -t 60 # -s 20: Requires at least 20 reads to support an SV for reporting. --> 10 # -l 50: Reports SVs that are at least 50 base pairs long. # -t 60: Uses 60 threads for faster processing. for sample in HD46_1 HD46_2 HD46_3 HD46_4 HD46_5 HD46_6 HD46_7 HD46_8 HD46_13; do #minimap2 --MD -t 60 -ax map-ont HD46_Ctrl_chr_plasmid.fasta ./batch1_depth25/trycycler_${sample}/reads.fastq | samtools sort -o ${sample}.sorted.bam minimap2 --MD -t 60 -ax map-ont HD46_Ctrl_chr_plasmid.fasta ${sample}.fastq.gz | samtools sort -o ${sample}_minimap2.sorted.bam samtools index ${sample}_minimap2.sorted.bam sniffles -m ${sample}_minimap2.sorted.bam -v ${sample}_minimap2+sniffles.vcf -s 10 -l 50 -t 60 #QUAL < 20 || bcftools filter -e "INFO/SVTYPE != 'INS'" ${sample}_minimap2+sniffles.vcf > ${sample}_minimap2+sniffles_filtered.vcf done #Estimating parameter... # Max dist between aln events: 44 # Max diff in window: 76 # Min score ratio: 2 # Avg DEL ratio: 0.0112045 # Avg INS ratio: 0.0364027 #Start parsing... CP020463 # # Processed reads: 10000 # # Processed reads: 20000 # Finalizing .. #Start genotype calling: # Reopening Bam file for parsing coverage # Finalizing .. #Estimating parameter... # Max dist between aln events: 28 # Max diff in window: 89 # Min score ratio: 2 # Avg DEL ratio: 0.013754 # Avg INS ratio: 0.17393 #Start parsing... CP020463 # # Processed reads: 10000 # # Processed reads: 20000 # # Processed reads: 30000 # # Processed reads: 40000 # Results: # * barcode01_minimap2+sniffles.vcf # * barcode01_minimap2+sniffles_filtered.vcf # * barcode02_minimap2+sniffles.vcf # * barcode02_minimap2+sniffles_filtered.vcf # * barcode03_minimap2+sniffles.vcf # * barcode03_minimap2+sniffles_filtered.vcf # * barcode04_minimap2+sniffles.vcf # * barcode04_minimap2+sniffles_filtered.vcf #ERROR: No MD string detected! Check bam file! Otherwise generate using e.g. samtools. --> No results! #for sample in barcode01 barcode02 barcode03 barcode04; do # sniffles -m svim_reads_minimap2_${sample}/${sample}.fastq.minimap2.coordsorted.bam -v sniffles_minimap2_${sample}.vcf -s 10 -l 50 -t 60 # bcftools filter -e "INFO/SVTYPE != 'INS'" sniffles_minimap2_${sample}.vcf > sniffles_minimap2_${sample}_filtered.vcf #done # ---- Option_3: NGMLR (aligner) + SVIM (structural variant caller) --> SUCCESSFUL ---- for sample in HD46_1 HD46_2 HD46_3 HD46_4 HD46_5 HD46_6 HD46_7 HD46_8 HD46_13; do svim reads --aligner ngmlr --nanopore ngmlr+svim_${sample} ${sample}.fastq.gz HD46_Ctrl_chr_plasmid.fasta --cores 10; done # ---- Option_4: NGMLR (aligner) + sniffles (structural variant caller) --> SUCCESSFUL ---- for sample in HD46_1 HD46_2 HD46_3 HD46_4 HD46_5 HD46_6 HD46_7 HD46_8 HD46_13; do sniffles -m ngmlr+svim_${sample}/${sample}.fastq.ngmlr.coordsorted.bam -v ${sample}_ngmlr+sniffles.vcf -s 10 -l 50 -t 60 bcftools filter -e "INFO/SVTYPE != 'INS'" ${sample}_ngmlr+sniffles.vcf > ${sample}_ngmlr+sniffles_filtered.vcf done #END -
Compare and integrate all results produced by minimap2+sniffles and ngmlr+sniffles, and check them each position in IGV!
# !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! # mv HD46_1_minimap2+sniffles_filtered.vcf HD46-1_minimap2+sniffles_filtered.vcf mv HD46_1_ngmlr+sniffles_filtered.vcf HD46-1_ngmlr+sniffles_filtered.vcf mv HD46_2_minimap2+sniffles_filtered.vcf HD46-2_minimap2+sniffles_filtered.vcf mv HD46_2_ngmlr+sniffles_filtered.vcf HD46-2_ngmlr+sniffles_filtered.vcf mv HD46_3_minimap2+sniffles_filtered.vcf HD46-3_minimap2+sniffles_filtered.vcf mv HD46_3_ngmlr+sniffles_filtered.vcf HD46-3_ngmlr+sniffles_filtered.vcf mv HD46_4_minimap2+sniffles_filtered.vcf HD46-4_minimap2+sniffles_filtered.vcf mv HD46_4_ngmlr+sniffles_filtered.vcf HD46-4_ngmlr+sniffles_filtered.vcf mv HD46_5_minimap2+sniffles_filtered.vcf HD46-5_minimap2+sniffles_filtered.vcf mv HD46_5_ngmlr+sniffles_filtered.vcf HD46-5_ngmlr+sniffles_filtered.vcf mv HD46_6_minimap2+sniffles_filtered.vcf HD46-6_minimap2+sniffles_filtered.vcf mv HD46_6_ngmlr+sniffles_filtered.vcf HD46-6_ngmlr+sniffles_filtered.vcf mv HD46_7_minimap2+sniffles_filtered.vcf HD46-7_minimap2+sniffles_filtered.vcf mv HD46_7_ngmlr+sniffles_filtered.vcf HD46-7_ngmlr+sniffles_filtered.vcf mv HD46_8_minimap2+sniffles_filtered.vcf HD46-8_minimap2+sniffles_filtered.vcf mv HD46_8_ngmlr+sniffles_filtered.vcf HD46-8_ngmlr+sniffles_filtered.vcf mv HD46_13_minimap2+sniffles_filtered.vcf HD46-13_minimap2+sniffles_filtered.vcf mv HD46_13_ngmlr+sniffles_filtered.vcf HD46-13_ngmlr+sniffles_filtered.vcf -
(NOT_USED) Filtering low-complexity insertions using RepeatMasker (TODO: how to use RepeatModeler to generate own lib?)
(scientific name), eubacteria (genbank common name), Monera (in-part), Procaryotae (in-part), Prokaryota (in-part), Prokaryotae (in-part), prokaryote (in-part), prokaryotes (in-part) Non-exact Matches ================= 1783272 Terrabacteria group (scientific name) 91061 Bacilli (scientific name), Bacilli Ludwig et al. 2010 (authority), Bacillus/Lactobacillus/Streptococcus group (synonym), Firmibacteria (synonym), Firmibacteria Murray 1988 (authority) 1239 Bacillaeota (synonym), Bacillaeota Oren et al. 2015 (authority), Bacillota (synonym), Bacillus/Clostridium group (synonym), clostridial firmicutes (synonym), Clostridium group firmicutes (synonym), Firmacutes (synonym), firmicutes (blast name), Firmicutes (scientific name), Firmicutes corrig. Gibbons and Murray 1978 (authority), Low G+C firmicutes (synonym), low G+C Gram-positive bacteria (common name), low GC Gram+ (common name) Summary of Classes within Firmicutes: * Bacilli (includes many common pathogenic and non-pathogenic Gram-positive bacteria, taxid=91061) * Bacillus (e.g., Bacillus subtilis, Bacillus anthracis) * Staphylococcus (e.g., Staphylococcus aureus, Staphylococcus epidermidis) * Streptococcus (e.g., Streptococcus pneumoniae, Streptococcus pyogenes) * Listeria (e.g., Listeria monocytogenes) * Clostridia (includes many anaerobic species like Clostridium and Clostridioides) * Erysipelotrichia (intestinal bacteria, some pathogenic) * Tissierellia (less-studied, veterinary relevance) * Mollicutes (cell wall-less, includes Mycoplasma species) * Negativicutes (includes some Gram-negative, anaerobic species) RepeatMasker -species Bacilli -pa 4 -xsmall variants.fasta python extract_unmasked_seq.py variants.fasta.masked unmasked_variants.fasta #bcftools filter -i ‘QUAL>30 && INFO/SVLEN>100’ variants.vcf -o filtered.vcf # #bcftools view -i ‘SVTYPE=”INS”‘ variants.vcf | bcftools query -f ‘%CHROM\t%POS\t%REF\t%ALT\t%INFO\n’ > insertions.txt #mamba install -c bioconda vcf2fasta #vcf2fasta variants.vcf -o insertions.fasta #grep “SEQS” variants.vcf | awk ‘{ print $1, $2, $4, $5, $8 }’ > insertions.txt #python3 filtering_low_complexity.py # #vcftools –vcf input.vcf –recode –out filtered_output –minSVLEN 100 #bcftools filter -e ‘INFO/SEQS ~ “^(G+|C+|T+|A+){4,}”‘ variants.vcf -o filtered.vcf # — calculate the percentage of reads To calculate the percentage of reads that contain the insertion from the VCF entry, use the INFO and FORMAT fields provided in the VCF record. Step 1: Extract Relevant Information In the provided VCF entry: RE (Reads Evidence): 733 – the total number of reads supporting the insertion. GT (Genotype): 1/1 – this indicates a homozygous insertion, meaning all reads covering this region are expected to have the insertion. AF (Allele Frequency): 1 – a 100% allele frequency, indicating that every read in this sample supports the insertion. DR (Depth Reference): 0 – the number of reads supporting the reference allele. DV (Depth Variant): 733 – the number of reads supporting the variant allele (insertion). Step 2: Calculate Percentage of Reads Supporting the Insertion Using the formula: Percentage of reads with insertion=(DVDR+DV)×100 Percentage of reads with insertion=(DR+DVDV)×100 Substitute the values: Percentage=(7330+733)×100=100% Percentage=(0+733733)×100=100% Conclusion Based on the VCF record, 100% of the reads support the insertion, indicating that the insertion is fully present in the sample (homozygous insertion). This is consistent with the AF=1 and GT=1/1 fields. * In your VCF file generated by Sniffles, the REF=N in the results has a specific meaning: * In a standard VCF, the REF field usually contains the reference base(s) at the variant position. * For structural variants (SVs), especially insertions, there is no reference sequence replaced; the insertion occurs between reference bases. * Therefore, Sniffles uses N as a placeholder in the REF field to indicate “no reference base replaced”. * The actual inserted sequence is then stored in the ALT field.python vcf_to_fasta.py variants.vcf variants.fasta #python filter_low_complexity.py variants.fasta filtered_variants.fasta retained_variants.fasta #Using RepeatMasker to filter the low-complexity fasta, the used h5 lib is /home/jhuang/mambaforge/envs/transposon_long/share/RepeatMasker/Libraries/Dfam.h5 #1.9G python /home/jhuang/mambaforge/envs/transposon_long/share/RepeatMasker/famdb.py -i /home/jhuang/mambaforge/envs/transposon_long/share/RepeatMasker/Libraries/Dfam.h5 names 'bacteria' | head Exact Matches ============= 2 bacteria (blast name), Bacteria -
Why some records have UNRESOLVED in the FILTER field in the Excel output.
1. Understanding the format The data appears to be structural variant (SV) calls from Sniffles, probably in a VCF-like tabular format exported to Excel: * gi|1176884116|gb|CP020463.1| → reference sequence * Positions: 1855752 and 2422820 * N → insertion event * SVLEN=999 → size of the insertion * AF → allele frequency * GT:DR:DV → genotype, depth reference, depth variant (1/1:0:678, example values for a PASS variant) * FILTER → whether the variant passed filters (UNRESOLVED means it didn’t pass) 2. What UNRESOLVED usually means In Sniffles: * UNRESOLVED is assigned to SVs when the tool cannot confidently resolve the exact sequence or breakpoint. * Reasons include: - Low read support (RE, DV) relative to the expected coverage - Ambiguous alignment at repetitive regions - Conflicting strand or orientation signals - Allele frequency inconsistent with expectations 3. Examine your two records First record POS: 1855752 SVTYPE: INS SVLEN: 999 RE: 68 AF: 1 GT: 1/1 FILTER: UNRESOLVED Observations: * AF = 1 → allele frequency 100%, homozygous insertion * RE = 68 → 68 reads support the variant, decent coverage * Still UNRESOLVED → likely because Sniffles could not resolve the inserted sequence precisely; sometimes long insertions in repetitive regions are hard to reconstruct fully even with good read support. Second record POS: 2422820 SVTYPE: INS SVLEN: 999 RE: 22 AF: 0.025522 GT: 0/0 FILTER: UNRESOLVED Observations: * AF = 0.0255 → very low allele frequency (~2.5%) * RE = 22, DR = 840 → very low variant reads vs reference * GT = 0/0 → homozygous reference * Sniffles marks it UNRESOLVED because the variant is essentially noise, not confidently detected. 4. Key difference between the two Feature First record Second record Allele frequency (AF) 1 (high) 0.0255 (very low) Variant reads (RE) 68 22 Genotype (GT) 1/1 0/0 Reason for UNRESOLVED Unresolvable inserted sequence ✅ 5. Conclusion * Sniffles marks a variant as UNRESOLVED when the SV cannot be confidently characterized. * Even if there is good read support (first record), complex insertions can’t always be reconstructed fully. * Very low allele frequency (second record) also triggers UNRESOLVED because the signal is too weak compared to background noise. * Essentially: “UNRESOLVED” ≠ bad data, it’s just unresolved uncertainty. -
(NOT_SURE_HOW_TO_USE) Polishing of assembly: Use tools like Medaka to refine variant calls by leveraging consensus sequences derived from nanopore data.
mamba install -c bioconda medaka medaka-consensus -i aligned_reads.bam -r reference.fasta -o polished_output -t 4 -
Compare Insertions Across Samples
Merge Variants Across Samples: Use SURVIVOR to merge and compare the detected insertions in all samples against the WT: SURVIVOR merge input_vcfs.txt 1000 1 1 1 0 30 merged.vcf Input: List of VCF files from Sniffles2. Output: A consolidated VCF file with shared and unique variants. Filter WT Insertions: Identify transposons present only in samples 1–9 by subtracting WT variants using bcftools: bcftools isec WT.vcf merged.vcf -p comparison_results -
Validate and Visualize
Visualize with IGV: Use IGV to inspect insertion sites in the alignment and confirm quality. igv.sh Validate Findings: Perform PCR or additional sequencing for key transposon insertion sites to confirm results. -
Alternatives to TEPID for Long-Read Data
If you’re looking for transposon-specific tools for long reads: REPET: A robust transposon annotation tool compatible with assembled genomes. EDTA (Extensive de novo TE Annotator): A pipeline to identify, classify, and annotate transposons. Works directly on your assembled genomes. perl EDTA.pl --genome WT.fasta --type all -
The WT.vcf file in the pipeline is generated by detecting structural variants (SVs) in the wild-type (WT) genome aligned against itself or using it as a baseline reference. Here’s how you can generate the WT.vcf:
Steps to Generate WT.vcf 1. Align WT Reads to the WT Reference Genome The goal here is to create an alignment of the WT sequencing data to the WT reference genome to detect any self-contained structural variations, such as native insertions, deletions, or duplications. Command using Minimap2: minimap2 -ax map-ont WT.fasta WT_reads.fastq | samtools sort -o WT.sorted.bam Index the BAM file: samtools index WT.sorted.bam 2. Detect Structural Variants with Sniffles2 Run Sniffles2 on the WT alignment to call structural variants: sniffles --input WT.sorted.bam --vcf WT.vcf This step identifies: Native transposons and insertions present in the WT genome. Other structural variants that are part of the reference genome or sequencing artifacts. Key parameters to consider: --min_support: Adjust based on your WT sequencing coverage. --max_distance: Define proximity for merging variants. --min_length: Set a minimum SV size (e.g., >50 bp for transposons). -
Clean and Filter the WT.vcf, Variant Filtering: Remove low-confidence variants based on read depth, quality scores, or allele frequency.
To ensure the WT.vcf only includes relevant transposons or SVs: Use bcftools or similar tools to filter out low-confidence variants: bcftools filter -e "QUAL < 20 || INFO/SVTYPE != 'INS'" WT.vcf > WT_filtered.vcf bcftools filter -e "QUAL < 1 || INFO/SVTYPE != 'INS'" 1_.vcf > 1_filtered_.vcf -
NOTE that in this pipeline, the WT.fasta (reference genome) is typically a high-quality genome sequence from a database or a well-annotated version of your species’ genome. It is not assembled from the WT.fastq sequencing reads in this context. Here’s why:
Polish the assembly using tools like Racon (with the same reads) or Medaka for higher accuracy. Use the assembled and polished genome as your WT.fasta reference for further steps. Key Takeaways: If you have access to a reliable, high-quality reference genome, use it as the WT.fasta. Only assemble WT.fasta from raw reads (WT.fastq) if no database reference is available for your organism.Why Use a Reference Genome (WT.fasta) from a Database? Higher Quality and Completeness: Database references (e.g., NCBI, Ensembl) are typically well-assembled, highly polished, and annotated. They serve as a reliable baseline for variant detection. Consistency: Using a standard reference ensures consistent comparisons across your WT and samples (1–9). Variants detected will be relative to this reference, not influenced by possible assembly errors. Saves Time: Assembling a reference genome from WT reads requires significant computational effort. Using an existing reference streamlines the analysis. Alternative: Assembling WT from FASTQ If you don’t have a high-quality reference genome (WT.fasta) and must rely on your WT FASTQ reads: Assemble the genome from your WT.fastq: Use long-read assemblers like Flye, Canu, or Shasta to create a draft genome. flye --nano-raw WT.fastq --out-dir WT_assembly --genome-size -
Annotate Transposable Elements: Tools like ANNOVAR or SnpEff provide functional insights into the detected variants.
# !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! # #Using snpEff to annotate the insertion! conda activate /home/jhuang/miniconda3/envs/spandx
# --> BUG:
LOCUS HD46_Ctrl 2707468 bp DNA circular BCT
02-OCT-2025
DEFINITION Staphylococcus epidermidis strain HD46-ctrl chromosome, whole
genome shotgun sequence.
ACCESSION
VERSION
# --> DEBUG: adapt the genbank-file header as follows:
LOCUS HD46_Ctrl 2707468 bp DNA circular BCT 02-OCT-2025
DEFINITION Staphylococcus epidermidis strain HD46-ctrl chromosome, whole
genome shotgun sequence.
ACCESSION HD46_Ctrl
VERSION HD46_Ctrl.1
DBLINK BioProject: PRJNA1337321
BioSample: SAMN52215988
KEYWORDS .
SOURCE Staphylococcus epidermidis
ORGANISM Staphylococcus epidermidis
Bacteria; Firmicutes; Bacilli; Bacillales; Staphylococcaceae;
Staphylococcus.
COMMENT Annotated genome for HD46_Ctrl.
... # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! #
mkdir ~/miniconda3/envs/spandx/share/snpeff-5.1-2/data/HD46_Ctrl
cp HD46_Ctrl_chr.gb ~/miniconda3/envs/spandx/share/snpeff-5.1-2/data/HD46_Ctrl/genes.gbk
vim ~/miniconda3/envs/spandx/share/snpeff-5.1-2/snpEff.config #HD46_Ctrl.genome : HD46_Ctrl
/home/jhuang/miniconda3/envs/spandx/bin/snpEff build -genbank HD46_Ctrl -d
sed -i 's/^cluster_001_consensus/HD46_Ctrl.1/' HD46-8_ngmlr+sniffles_filtered.vcf
sed -i 's/^cluster_001_consensus/HD46_Ctrl.1/' HD46-13_ngmlr+sniffles_filtered.vcf
#snpEff eff -nodownload -no-downstream -no-intergenic -ud 100 -v HD46_Ctrl HD46-8_ngmlr+sniffles_filtered.vcf > HD46-8_ngmlr+sniffles_filtered.annotated.vcf
#snpEff eff -nodownload -no-downstream -no-intergenic -ud 100 -v HD46_Ctrl HD46-13_ngmlr+sniffles_filtered.vcf > HD46-13_ngmlr+sniffles_filtered.annotated.vcf
# HD46-8
snpEff ann -Xmx8g -v -hgvs -canon -ud 200 \
-stats HD46-8_snpeff_stats.html \
HD46_Ctrl \
HD46-8_ngmlr+sniffles_filtered.vcf \
> HD46-8_ngmlr+sniffles_filtered.annotated.vcf
# HD46-13
snpEff ann -Xmx8g -v -hgvs -canon -ud 200 \
-stats HD46-13_snpeff_stats.html \
HD46_Ctrl \
HD46-13_ngmlr+sniffles_filtered.vcf \
> HD46-13_ngmlr+sniffles_filtered.annotated.vcf-
Summarize the results as a Excel-file
# !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! # conda activate plot-numpy1 #python generate_common_vcf.py #mv common_variants.xlsx putative_transposons.xlsx # * Reads each of your VCFs. # * Filters variants → only keep those with FILTER == PASS. # * Compares the two aligner methods (minimap2+sniffles2 vs ngmlr+sniffles2) per sample. # * Keeps only variants that appear in both methods for the same sample. # * Outputs: An Excel file with the common variants and a log text file listing which variants were filtered out, and why (not_PASS or not_COMMON_in_two_VCF). #python generate_fuzzy_common_vcf_v1.py #Sample PASS_minimap2 PASS_ngmlr COMMON # HD46-Ctrl_Ctrl 39 29 28 # HD46-1 39 32 29 # HD46-2 40 32 28 # HD46-3 38 30 27 # HD46-4 46 35 32 # HD46-5 40 35 31 # HD46-6 43 35 30 # HD46-7 40 33 28 # HD46-8 37 20 11 # HD46-13 39 38 27 #Sample PASS_minimap2 PASS_ngmlr COMMON_FINAL #HD46-Ctrl_Ctrl 39 29 6 #HD46-1 39 32 8 #HD46-2 40 32 8 #HD46-3 38 30 6 #HD46-4 46 35 8 #HD46-5 40 35 9 #HD46-6 43 35 10 #HD46-7 40 33 8 #HD46-8 37 20 4 #HD46-13 39 38 5 # !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! # #!!!! Summarize the results of ngmlr+sniffles !!!! python merge_ngmlr+sniffles_filtered_results_and_summarize.py #!!!! Post-Processing !!!! #DELETE "2186168 N. PASS” in Sheet HD46-13 and Summary #DELETE “2427785 N CGTCAGAATCGCTGTCTGCGTCCGAGTCACTGTCTGAGTCTGAATCACTATCTGCGTCTGAGTCACTGTCTG . PASS” due to “0/1:169:117” in HD46-13 and Summary #DELETE “2441640 N GCTCATTAAGAATCATTAAATTAC . PASS” due to 0/1:170:152 in HD46-13 and Summary
-
Source code of merge_ngmlr+sniffles_filtered_results_and_summarize.py
python add_ann_to_excel.py --excel merged_ngmlr+sniffles_variants.xlsx --sheet8 "HD46-8" --sheet13 "HD46-13" --vcf8 HD46-8_ngmlr+sniffles_filtered.annotated.vcf --vcf13 HD46-13_ngmlr+sniffles_filtered.annotated.vcf --out merged_ngmlr+sniffles_variants_with_ANN.xlsx #!/usr/bin/env python3 # -*- coding: utf-8 -*- """ Add SnpEff ANN columns (for SVTYPE=INS) from annotated VCFs into an Excel workbook, with detailed debug about why CHROM+POS may not match. Key improvements: - Stronger CHROM/POS normalization (strip 'chr', unify MT naming, coerce numbers). - Explicit detection and logging of sheet key columns used. - Debug block prints: * Unique key counts in sheet vs VCF (before/after normalization) * Example non-matching keys from the sheet and from the VCF (top N) * Chromosome naming diagnostics (e.g., 'chr' presence, 'MT'/'M' harmonization) * Off-by-N diagnostics via --pos_tolerance (counts for would-match @ ±N) * Optional preview of the sheet's SV type column, if present - Safer ANN parsing and aggregation. - Command-line options: --debug_examples, --pos_tolerance ANN filling is done only for **exact** (CHROM, POS) equality (as before). Tolerance is used only for *diagnostics*, not for filling, to avoid incorrect merges. """ import argparse import gzip import io import re from pathlib import Path from typing import List, Tuple, Dict, Iterable, Set import pandas as pd FALLBACK_ANN_FIELDS: List[str] = [ 'Allele','Annotation','Annotation_Impact','Gene_Name','Gene_ID', 'Feature_Type','Feature_ID','Transcript_BioType','Rank','HGVS.c', 'HGVS.p','cDNA.pos/cDNA.length','CDS.pos/CDS.length','AA.pos/AA.length', 'Distance','Errors_Warnings_Info' ] def open_text_maybe_gzip(path: Path): if str(path).endswith('.gz'): return io.TextIOWrapper(gzip.open(path, 'rb'), encoding='utf-8', errors='ignore') return open(path, 'r', encoding='utf-8', errors='ignore') def normalize_chrom(col: pd.Series) -> pd.Series: s = col.astype(str).str.strip() s = s.str.replace(r'^(chr|CHR)', '', regex=True) # Standardize mitochondrial names to "MT" s = s.str.replace(r'^(M|MtDNA|MTDNA|Mito|Mitochondrion)$', 'MT', regex=True, case=False) return s.str.upper() def normalize_pos(col: pd.Series) -> pd.Series: # Excel can make ints look like floats; coerce then Int64 # (We keep Int64 nullable for robustness; we never compare NaNs.) s = pd.to_numeric(col, errors='coerce') # If people had 0-based starts in the sheet (rare for INS), this won't fix it, # but the tolerance debug will reveal a +1 shift if present. return s.astype('Int64') def parse_vcf_ann(vcf_path: Path) -> Tuple[pd.DataFrame, List[str]]: ann_fields = None header_cols = None records = [] with open_text_maybe_gzip(vcf_path) as f: for line in f: if line.startswith('##INFO=<ID=ANN'): m = re.search(r'Format:\s*([^">]+)', line) if m: ann_fields = [s.strip() for s in m.group(1).split('|')] if line.startswith('#CHROM'): header_cols = line.strip().lstrip('#').split('\t') break if not header_cols: raise RuntimeError(f"Could not find VCF header line (#CHROM ...) in {vcf_path}") if not ann_fields: ann_fields = FALLBACK_ANN_FIELDS ann_cols = [f'ANN_{x}' for x in ann_fields] for line in f: if not line or line[0] == '#': continue parts = line.rstrip('\n').split('\t') if len(parts) < len(header_cols): continue row = dict(zip(header_cols, parts)) info = row.get('INFO', '') # Only INS if not re.search(r'(?:^|;)SVTYPE=INS(?:;|$)', info): continue chrom = row.get('#CHROM') or row.get('CHROM') pos_str = row.get('POS') try: pos = int(pos_str) except Exception: continue # Extract ANN entries ann_match = re.search(r'(?:^|;)ANN=([^;]+)', info) ann_entries = ann_match.group(1).split(',') if ann_match else [] field_values: Dict[str, List[str]] = {k: [] for k in ann_fields} for ann in ann_entries: items = ann.split('|') if len(items) < len(ann_fields): items += [''] * (len(ann_fields) - len(items)) elif len(items) > len(ann_fields): items = items[:len(ann_fields)] for k, v in zip(ann_fields, items): field_values[k].append(v) joined = {f'ANN_{k}': (';'.join(v) if v else '') for k, v in field_values.items()} records.append({'CHROM': chrom, 'POS': pos, **joined}) df = pd.DataFrame.from_records(records) if not df.empty: df['POS'] = pd.to_numeric(df['POS'], errors='coerce').astype('Int64') df['CHROM'] = normalize_chrom(df['CHROM']) return df, ann_cols def detect_key_columns(df: pd.DataFrame) -> Dict[str, str]: chrom_candidates = ['CHROM', '#CHROM', 'Chrom', 'Chromosome', 'chrom', 'chr', 'Chr'] pos_candidates = ['POS', 'Position', 'position', 'pos', 'Start', 'start'] mapping = {} for c in chrom_candidates: if c in df.columns: mapping['CHROM'] = c break for p in pos_candidates: if p in df.columns: mapping['POS'] = p break return mapping def normalize_chrom_pos_df(df: pd.DataFrame, keys: Dict[str, str]) -> pd.DataFrame: out = df.copy() out[keys['CHROM']] = normalize_chrom(out[keys['CHROM']]) out[keys['POS']] = normalize_pos(out[keys['POS']]) return out def summarize_chr_formats(series: pd.Series, label: str): raw = series.astype(str) has_chr_prefix = raw.str.startswith(('chr','CHR')).sum() mt_like = raw.str.fullmatch(r'(M|MtDNA|MTDNA|Mito|Mitochondrion)', case=False).sum() print(f"[{label}] CHROM diagnostics:") print(f" total rows: {len(raw)}") print(f" with 'chr'/'CHR' prefix: {has_chr_prefix}") print(f" mitochondrial names like M/MtDNA/etc: {mt_like}") def keys_set(df: pd.DataFrame, chrom_col: str, pos_col: str) -> Set[Tuple[str, int]]: # Drop NA POS, NA CHROM sub = df[[chrom_col, pos_col]].dropna() # Ensure ints (drop NA after coercion) sub = sub[(sub[pos_col].astype('Int64').notna())] return set(zip(sub[chrom_col].astype(str), sub[pos_col].astype('int64'))) def tolerance_match_count(sheet_keys: Iterable[Tuple[str,int]], vcf_keys: Set[Tuple[str,int]], tol: int) -> int: if tol <= 0: return sum(1 for k in sheet_keys if k in vcf_keys) cnt = 0 for chrom, pos in sheet_keys: if (chrom, pos) in vcf_keys: cnt += 1 else: matched = False # check +/- 1..tol for d in range(1, tol+1): if (chrom, pos - d) in vcf_keys or (chrom, pos + d) in vcf_keys: matched = True break if matched: cnt += 1 return cnt def debug_match_report(df_sheet: pd.DataFrame, vcf_df: pd.DataFrame, keys: Dict[str, str], debug_examples: int = 15, pos_tolerance: int = 1): print("\n=== DEBUG: Matching overview ===") # Raw diagnostics summarize_chr_formats(df_sheet[keys['CHROM']], label="SHEET (raw)") summarize_chr_formats(vcf_df['CHROM'], label="VCF (normalized)") # Normalize sheet df_norm = normalize_chrom_pos_df(df_sheet, keys) print(f"Detected key columns -> CHROM: '{keys['CHROM']}' POS: '{keys['POS']}'") # Basic stats n_sheet_all = len(df_sheet) n_sheet_key_nonnull = df_norm[keys['CHROM']].notna().sum() - df_norm[keys['CHROM']].isna().sum() n_sheet_pos_nonnull = df_norm[keys['POS']].notna().sum() print(f"SHEET rows total: {n_sheet_all}") print(f"SHEET rows with non-null CHROM: {n_sheet_key_nonnull}, non-null POS: {n_sheet_pos_nonnull}") # Unique key counts sheet_norm_keys_df = df_norm.rename(columns={keys['CHROM']: 'CHROM', keys['POS']: 'POS'}) sheet_norm_keys_df = sheet_norm_keys_df.dropna(subset=['CHROM','POS']) sheet_norm_keys_df['POS'] = sheet_norm_keys_df['POS'].astype('Int64') sheet_keys_unique = keys_set(sheet_norm_keys_df, 'CHROM', 'POS') vcf_keys_unique = keys_set(vcf_df, 'CHROM', 'POS') print(f"Unique (CHROM,POS) keys -> SHEET: {len(sheet_keys_unique)} VCF(INS): {len(vcf_keys_unique)}") # Exact match count exact_matches = len(sheet_keys_unique & vcf_keys_unique) print(f"Exact key matches (SHEET∩VCF): {exact_matches}") # Tolerance diagnostics (diagnose off-by-one etc.) if pos_tolerance > 0: approx_matches = tolerance_match_count(sheet_keys_unique, vcf_keys_unique, pos_tolerance) print(f"Keys that would match within ±{pos_tolerance}: {approx_matches}") # Show some examples of non-matching keys from SHEET if debug_examples > 0: not_in_vcf = sorted(k for k in sheet_keys_unique if k not in vcf_keys_unique) not_in_sheet = sorted(k for k in vcf_keys_unique if k not in sheet_keys_unique) print(f"\nExamples of SHEET keys not found in VCF (showing up to {debug_examples}):") for k in not_in_vcf[:debug_examples]: print(" SHEET-only:", k) print(f"\nExamples of VCF keys not found in SHEET (showing up to {debug_examples}):") for k in not_in_sheet[:debug_examples]: print(" VCF-only:", k) # Try to detect a type column and report counts type_cols = [c for c in df_sheet.columns if c.lower() in ('svtype','type','variant_type','sv_type')] if type_cols: tcol = type_cols[0] is_ins = df_sheet[tcol].astype(str).str.upper() == 'INS' print(f"\nType column detected: '{tcol}'. SHEET rows with INS: {int(is_ins.sum())} / {len(df_sheet)}") # Of the INS rows, how many have keys that match? ins_keys = keys_set(df_norm[is_ins], keys['CHROM'], keys['POS']) exact_ins_matches = len(ins_keys & vcf_keys_unique) print(f" INS-only exact key matches: {exact_ins_matches} / {len(ins_keys)}") if pos_tolerance > 0: approx_ins_matches = tolerance_match_count(ins_keys, vcf_keys_unique, pos_tolerance) print(f" INS-only matches within ±{pos_tolerance}: {approx_ins_matches} / {len(ins_keys)}") else: print("\nNo explicit type column found in SHEET.") def merge_ann_into_sheet(df_sheet: pd.DataFrame, vcf_df: pd.DataFrame, ann_cols: List[str], pos_tolerance: int = 1, debug_examples: int = 15) -> pd.DataFrame: df = df_sheet.copy() keys = detect_key_columns(df) if 'CHROM' not in keys or 'POS' not in keys: print("WARNING: Could not detect CHROM/POS columns in sheet; ANN columns will be empty.") for c in ann_cols: if c not in df.columns: df[c] = '' return df # DEBUG: run a comprehensive match report debug_match_report(df, vcf_df, keys, debug_examples=debug_examples, pos_tolerance=pos_tolerance) # Normalize sheet keys for merge df_norm = normalize_chrom_pos_df(df, keys) # Prepare VCF map (unique by CHROM,POS), aggregate ANN fields vcf_use = vcf_df.copy() if vcf_use.empty: print("NOTE: No INS records found in VCF; ANN columns will be created but empty.") else: agg = {c: lambda s: ';'.join([x for x in s.astype(str).tolist() if x]) for c in ann_cols} vcf_use = vcf_use.groupby(['CHROM', 'POS'], as_index=False).agg(agg) # Identify potential type column in sheet type_cols = [c for c in df.columns if c.lower() in ('svtype','type','variant_type','sv_type')] has_type = bool(type_cols) if has_type: tcol = type_cols[0] is_ins = df[tcol].astype(str).str.upper() == 'INS' print(f"\nMERGE: using type column '{tcol}' -> rows marked INS: {int(is_ins.sum())} / {len(df)}") else: is_ins = pd.Series([False]*len(df), index=df.index) print("\nMERGE: no type column -> will fill ANN wherever exact (CHROM,POS) matches VCF INS.") # Left merge on exact keys only (do not use tolerance for filling, just for diagnostics) left = df_norm.rename(columns={keys['CHROM']: 'CHROM', keys['POS']: 'POS'}) merged = left.merge(vcf_use[['CHROM','POS'] + ann_cols], on=['CHROM','POS'], how='left', suffixes=('','')) # Initialize ANN columns on original df for c in ann_cols: if c not in df.columns: df[c] = '' # Fill values: for c in ann_cols: values = merged[c] if has_type: df.loc[is_ins, c] = values[is_ins].fillna('').astype(str).values else: df[c] = values.fillna('').astype(str).values # Report matching stats on the actual merge matched = merged[ann_cols].notna().any(axis=1).sum() print(f"\nMERGE RESULT: rows with any ANN filled (exact VCF match): {int(matched)} / {len(df)}") # Additional hint if tolerance suggests many near-misses if pos_tolerance > 0: sheet_keys = keys_set(left, 'CHROM', 'POS') vcf_keys_unique = keys_set(vcf_use, 'CHROM', 'POS') approx = tolerance_match_count(sheet_keys, vcf_keys_unique, pos_tolerance) if approx > matched: print(f"NOTE: There appear to be {approx - matched} additional rows that would match within ±{pos_tolerance}.") print(" This often indicates a 0-based vs 1-based position shift or use of END instead of POS in the sheet.") return df def main(): ap = argparse.ArgumentParser() ap.add_argument('--excel', default='merged_ngmlr+sniffles_variants.xlsx', help='Input Excel workbook') ap.add_argument('--sheet8', default='HD46-8', help='Sheet name for HD46-8 sample') ap.add_argument('--sheet13', default='HD46-13', help='Sheet name for HD46-13 sample') ap.add_argument('--vcf8', default='HD46-8_ngmlr+sniffles_filtered.annotated.vcf', help='Annotated VCF for HD46-8') ap.add_argument('--vcf13', default='HD46-13_ngmlr+sniffles_filtered.annotated.vcf', help='Annotated VCF for HD46-13') ap.add_argument('--out', default='merged_ngmlr+sniffles_variants_with_ANN.xlsx', help='Output Excel path') ap.add_argument('--debug_examples', type=int, default=15, help='How many non-match examples to print from each side') ap.add_argument('--pos_tolerance', type=int, default=1, help='Diagnostic tolerance (±N bp) for off-by-N checks (used for debug only)') args = ap.parse_args() excel_path = Path(args.excel) vcf8_path = Path(args.vcf8) vcf13_path = Path(args.vcf13) out_path = Path(args.out) # Load sheets (resolve case-insensitive names) xls = pd.ExcelFile(excel_path) def resolve_sheet(name: str) -> str: if name in xls.sheet_names: return name lower_map = {s.lower(): s for s in xls.sheet_names} return lower_map.get(name.lower(), name) sheet8 = resolve_sheet(args.sheet8) sheet13 = resolve_sheet(args.sheet13) df8 = pd.read_excel(excel_path, sheet_name=sheet8) df13 = pd.read_excel(excel_path, sheet_name=sheet13) # Parse VCFs (INS only) vcf8_df, ann_cols = parse_vcf_ann(vcf8_path) vcf13_df, _ = parse_vcf_ann(vcf13_path) print(f"VCF8 INS variants: {len(vcf8_df)}; VCF13 INS variants: {len(vcf13_df)}") print(f"ANN subfields ({len(ann_cols)}): {', '.join(ann_cols)}") # Merge with diagnostics df8_out = merge_ann_into_sheet(df8, vcf8_df, ann_cols, pos_tolerance=args.pos_tolerance, debug_examples=args.debug_examples) df13_out = merge_ann_into_sheet(df13, vcf13_df, ann_cols, pos_tolerance=args.pos_tolerance, debug_examples=args.debug_examples) # Save with pd.ExcelWriter(out_path, engine='xlsxwriter') as writer: df8_out.to_excel(writer, sheet_name=sheet8, index=False) df13_out.to_excel(writer, sheet_name=sheet13, index=False) print(f"\nDone. Wrote: {out_path.resolve()}") if __name__ == '__main__': main() -
Manually merge all contents of ANN=? to a seperate column ‘ANN’ in the isolate-specific sheets in the Excel-file.
#Add CHROM and HD46_Ctrl.1 to first column of the input Excel-file (plot-numpy1) jhuang@WS-2290C:~/DATA/Data_Patricia_Transposon_2025$ python add_ann_to_excel.py --excel merged_ngmlr+sniffles_variants.xlsx --sheet8 "HD46-8" --sheet13 "HD46-13" --vcf8 HD46-8_ngmlr+sniffles_filtered.annotated.vcf --vcf13 HD46-13_ngmlr+sniffles_filtered.annotated.vcf --out merged_ngmlr+sniffles_variants_with_ANN.xlsx #DEL some columns (INFO, NN_Allele, ANN_Rank, ANN_Errors_Warnings_Info, from the table, and COPY the summary-sheet to the final table. -
Run nextflow bacass
# -- samplesheet_bacass.tsv -- #ID R1 R2 LongFastQ Fast5 GenomeSize #HD46_Ctrl HD46_Ctrl.fastq.gz NA NA #HD46_1 HD46_1.fastq.gz NA NA #An6 /mnt/md1/DATA/Data_Tam_DNAseq_2026_An6_BG5/X101SC26036392-Z01-J002/clean_data/An6/An6_L1_1.clean.rd.fq.gz /mnt/md1/DATA/Data_Tam_DNAseq_2026_An6_BG5/X101SC26036392-Z01-J002/clean_data/An6/An6_L1_2.clean.rd.fq.gz /mnt/md1/DATA/Data_Tam_DNAseq_2026_An6_BG5/X101SC26036392-Z01-J003/Release-X101SC26036392-Z01-J003-20260513_01/Data-X101SC26036392-Z01-J003/An6/2157_4C_PBK79106_7ec05c46/merged_An6_longreads.fastq.gz NA 2.7m #BG5 /mnt/md1/DATA/Data_Tam_DNAseq_2026_An6_BG5/X101SC26036392-Z01-J002/clean_data/BG5/BG5_L1_1.clean.rd.fq.gz /mnt/md1/DATA/Data_Tam_DNAseq_2026_An6_BG5/X101SC26036392-Z01-J002/clean_data/BG5/BG5_L1_2.clean.rd.fq.gz /mnt/md1/DATA/Data_Tam_DNAseq_2026_An6_BG5/X101SC26036392-Z01-J003/Release-X101SC26036392-Z01-J003-20260513_01/Data-X101SC26036392-Z01-J003/BG5/2157_4C_PBK79106_7ec05c46/merged_BG5_longreads.fastq.gz NA 6.5m conda deactivate # DEBUG: --kmerfinderdb /mnt/nvme1n1p1/REFs/kmerfinder/bacteria/ not working, maybe due to the version, since 2.5.0 was working (see below)! #nextflow run nf-core/bacass -r 2.5.0 -profile docker \ #--input samplesheet.tsv \ #--outdir bacass_out \ #--assembly_type long \ #--kraken2db /mnt/nvme1n1p1/REFs/k2_standard_08_GB_20251015.tar.gz \ #--kmerfinderdb /mnt/nvme1n1p1/REFs/kmerfinder/bacteria/ \ #-resume #For hybrid-assembly: --assembly_type hybrid --assembler unicycler,dragonflye [unicycler,autocycler,canu,dragonflye,flye,miniasm,raven,megahit] \ nextflow run nf-core/bacass -r 2.6.0 -profile docker --help nextflow run nf-core/bacass -r 2.6.0 -profile docker \ --input samplesheet_bacass.tsv \ --outdir bacass_out \ --assembly_type long \ --assembler unicycler,dragonflye \ --kraken2db /mnt/nvme1n1p1/REFs/k2_standard_08_GB_20251015.tar.gz \ --skip_kmerfinder \ -resume \ -c unicycler.config \ -work-dir bacass_out/work #SAVE bacass_out/Kmerfinder/kmerfinder_summary.csv to bacass_out/Kmerfinder/An6?/An6?_kmerfinder_results.xlsx #busco example results: Input_file Dataset Complete Single Duplicated Fragmented Missing n_markers Scaffold N50 Contigs N50 Percent gaps Number of scaffolds wt_cef.scaffolds.fa bacteria_odb10 98.4 98.4 0.0 1.6 0.0 124 285852 285852 0.000% 45 wt_cipro.scaffolds.fa bacteria_odb10 90.3 89.5 0.8 8.1 1.6 124 7434 7434 0.000% 1699 -
Detecting the next closest genome
mamba activate gtdbtk # 验证环境变量是否加载成功 echo $GTDBTK_DATA_PATH # 应输出:/mnt/nvme4n1p1/gtdb_data/release232 # 3. 运行分类(你提供的命令 + 实用参数) gtdbtk classify_wf \ --genome_dir ./bacass_out/Medaka \ --out_dir gtdb_out \ --cpus 64 \ --extension .fa \ --prefix mygenome # 4. 查看结果 cat gtdb_out/classify/mygenome.bac120.summary.tsv # 细菌结果 -
Structural variant calling
conda activate sv_assembly # MLST calling for sample in HD46_Ctrl HD46_1 HD46_2 HD46_3 HD46_4 HD46_5 HD46_6 HD46_7 HD46_8 HD46_13 _WT _1 _2 _3 _4 _5 _7 _8 _9 _10; do mlst bacass_out/Medaka/${sample}-unicycler-medaka_polished_genome.fa >> mlst_res done # After running MLST and genome taxonomy checks, I found that CP020463 is only a suitable reference for the first dataset (_WT, _1–_10), because all of these samples share ST 86 — the same sequence type as CP020463. For the second dataset (HD46 series), CP020463 is not an appropriate reference. MLST and GTDB-Tk classification results (see mygenome.bac120.summary2.xlsx and mlst_res.xlsx) show that these genomes are genetically distinct. for sample in _WT _1 _2 _3 _4 _5 _7 _8 _9 _10; do nucmer --maxmatch -l 100 -c 500 CP020463.fasta bacass_out/Medaka/${sample}-dragonflye-medaka_polished_genome.fa -p ${sample}; delta-filter -1 -q ${sample}.delta > ${sample}.filtered.delta; #Usage: Assemblytics delta output_prefix unique_length_required min_size max_size Assemblytics ${sample}.filtered.delta ${sample}_assemblytics 1000 100 500000; done samtools faidx bacass_out/Medaka/HD46_Ctrl-dragonflye-medaka_polished_genome.fa contig00001 > bacass_out/Medaka/HD46_Ctrl_chrom.fa for sample in HD46_1 HD46_2 HD46_5 HD46_6 HD46_7; do nucmer --maxmatch -l 100 -c 500 bacass_out/Medaka/HD46_Ctrl_chrom.fa bacass_out/Medaka/${sample}-dragonflye-medaka_polished_genome.fa -p ${sample}; delta-filter -1 -q ${sample}.delta > ${sample}.filtered.delta; #Usage: Assemblytics delta output_prefix unique_length_required min_size max_size; Note that we use a large threshold 500,000 nt. Assemblytics ${sample}.filtered.delta ${sample}_assemblytics 1000 100 500000; done ./merge_variants.sh #!/bin/bash # Define the output file name OUTPUT="merged_assemblytics_variants.txt" # 1. Write the header with the new 'Sample' column # We read the header from the first file, strip the '#', and append 'Sample' head -n 1 *_assemblytics.variant_preview.txt | grep '^#' | sed 's/^#//' | awk '{print $0 "\tSample"}' > "$OUTPUT" # 2. Loop through all matching files for file in *_assemblytics.variant_preview.txt; do # Extract sample name (e.g., "HD46_Ctrl" from "HD46_Ctrl_assemblytics.variant_preview.txt") sample=$(echo "$file" | sed 's/_assemblytics\.variant_preview\.txt//') # Append data lines, skipping the header line (lines starting with '#') # and append the sample name as the last column grep -v '^#' "$file" | awk -v samp="$sample" '{print $0 "\t" samp}' >> "$OUTPUT" done echo "✅ Successfully merged $(ls *_assemblytics.variant_preview.txt | wc -l) files into $OUTPUT" #Manually sorted the generated file merged_assemblytics_variants.txt into two parts: one is HD46-series and one is _*series. unicycler -l HD46_Ctrl.fastq.gz --mode normal -t 40 -o HD46_Ctrl_unicycler_normal unicycler -l HD46_3.fastq.gz --mode normal -t 40 -o HD46_3_unicycler_normal unicycler -l HD46_4.fastq.gz --mode normal -t 40 -o HD46_4_unicycler_normal unicycler -l HD46_13.fastq.gz --mode normal -t 40 -o HD46_13_unicycler_normal