Basic Information about Mutation.
| Gene Information |
Gene Name |
ODBHLOBF_00022 |
| Gene Type |
protein_coding |
| Mutation type |
stop_lost&splice_region_variant |
| Genome position |
17193 |
| Reference genome |
1111525849736575_bin.9__k141_15879 |
| DNA Level |
DNA Mutation: 1190A>G |
| Ref Seq: T |
| Mut Seq: C |
| Protein Level |
Protein 1-letter Mutation: NA397W |
| Protein 3-letter Mutation: Ter397Trpext*? |
Analyzing the distribution of mutation across skin, oral, gut, and vaginal tissues.
The table summarizes the frequency and tissue-specific distribution of plasmid mutations detected in human skin, oral, gut, and vaginal microbiomes.
Note: The mutation frequency of each mutation was calculated separately for each plasmid cluster and tissue. The biological effects of the identified mutations were annotated using SnpEff.
| Mutation ID |
Gene Name |
Position |
Mutation Count |
Mutation Frequency |
Tissue Distribution |
Biotype |
Consequence |
Mutation Impact |
| M0021805 |
ODBHLOBF_00022 |
17193 |
3 |
0.08 |
Skin |
protein_coding |
stop_lost&splice_region_variant |
HIGH |
Investigating natural selection at mutation site for genetic adaptation and diversity
The MEME method within the HyPhy software was employed to analyze positive selection. MEME: episodic selection.
Note: List of sites found to be under episodic selection by MEME (p < 0.05). "Protein Start" corresponds to the protein's starting genomic position. "Protein End" corresponds to the protein's ending genomic position. The term 'site' represents a selection site within the protein.
| Protein name |
Protein start |
Protein end |
Protein length |
Site |
P-value |
Plasmid cluster |
Method |
The FEL method within the HyPhy software was employed to analyze both positive and negative selection. FEL: pervasive selection on samll datasets.
Note: List of sites found to be under pervasive selection by FEL (p < 0.05). A beta value greater than alpha signifies positive selection, while a beta value smaller than alpha signifies negative selection. "Protein Start" corresponds to the protein's starting genomic position. "Protein End" corresponds to the protein's ending genomic position. The term 'site' represents a selection site within the protein.
| Protein name |
Protein start |
Protein end |
Protein length |
Site |
Alpha |
Beta |
P-value |
Plasmid cluster |
Method |
Alterations in protein physicochemical properties induced by mutation
Understanding the alterations in protein physicochemical properties can reveal the evolutionary processes and adaptive changes of viruses
Note: ProtParam software was used for the analysis of physicochemical properties. Significant change threshold: A change exceeding 10% compared to the reference is considered a significant change. "GRAVY" is an abbreviation for "grand average of hydropathicity".
| Group |
Protein name |
Molecular weight |
Theoretical PI |
Extinction coefficients |
Aliphatic index |
instability_index |
instability_classifies |
Alterations in protein stability induced by mutation
The impact of mutations on protein stability directly or indirectly affects the biological characteristics, adaptability, and transmission capacity of the virus
Note: iMutant 2.0 was utilized to analyze the effects of mutations on protein stability. pH 7 and a temperature of 25°C are employed to replicate the in vitro environment. pH 7.4 and a temperature of 37°C are utilized to simulate the in vivo environment.
| Mutation |
Mutation type |
Position |
ΔDDG |
Stability |
pH |
Temperature |
Condition |
Tissue |
Alterations in enzyme cleavage sites induced by mutation
Exploring the impact of mutations on the cleavage sites of 28 enzymes.
Note: The PeptideCutter software was used for detecting enzymes cleavage sites. The increased enzymes cleavage sites refer to the cleavage sites in the mutated protein that are added compared to the reference protein. Conversely, the decreased enzymes cleavage sites indicate the cleavage sites in the mutated protein that are reduced compared to the reference protein.
| Mutation |
Protein name |
Genome position |
Enzyme name |
Increased cleavage sites |
Decreased cleavage sites |
Impact of mutation on antigenicity and immunogenicity
Investigating the impact of mutations on antigenicity and immunogenicity carries important implications for vaccine design and our understanding of immune responses.
Note: An absolute change greater than 0.0102 (three times the median across sites) in antigenicity score is considered significant. An absolute changegreater than 0.2754 (three times the median across sites) in immunogenicity score is considered significant. The VaxiJen tool was utilized for antigenicity analysis. The IEDB tool was used for immunogenicity analysis. Antigens with a prediction score of more than 0.4 for this tool are considered candidate antigens. MHC I immunogenicity score >0, indicating a higher probability to stimulate an immune response.
| Group |
Protein name |
Protein region |
Antigenicity score |
Immunogenicity score |
Analysis of virulence factors contributing to bacterial pathogenicity
The table lists virulence factors linked to this mutation.
Note: Virulence factor analysis was performed using VFDB. Genes in plasmid clusters showing strong homology (identity > 70%, coverage > 70%, E-value < 1e-5) to known virulence factors are listed.
| gname |
vf_name |
vf_gene_id |
vf_category |
q_start |
q_end |
query_coverage |
subject_coverage |
identity |
evalue |
gene_description |
group |
Analysis of biocide and heavy metal resistance genes to assess antimicrobial risk and environmental impact
The table lists biocide and heavy metal resistance genes linked to this mutation.
Note: Analyzing biocide and heavy metal resistance genes based on BacMet to evaluate bacterial resistance risk and the potential impact of environmental heavy metal contamination. Genes in plasmid clusters showing strong homology (identity > 70%, subject coverage > 70%, E-value < 1e-5) to known biocide and heavy metal resistance genes are listed.
| gname |
subject |
accession |
q_start |
q_end |
query_coverage |
subject_coverage |
identity |
evalue |
compound |
group |
Analyzing antimicrobial resistance genes to assess bacterial resistance to antibiotics and other antimicrobial agents
The table lists antimicrobial resistance genes linked to this mutation.
Note: Antimicrobial resistance was performed using CARD. Genes in plasmid clusters showing strong homology (identity > 70%, coverage > 70%, E-value < 1e-5) to known antimicrobial resistance genes are listed.
| gname |
aro_name |
amr_gene_family |
aro_accession |
q_start |
q_end |
query_coverage |
subject_coverage |
identity |
evalue |
drug_class |
resistance_mechanism |
Analysis of pathogenicity genes to explore pathogen-host interactions
The table lists pathogenicity genes linked to this mutation.
Note: Analyzing pathogenicity-related genes using PHI-base to understand pathogen virulence mechanisms and their impact on host interactions. Genes in plasmid clusters showing strong homology (identity > 70%, subject coverage > 70%, and E-value < 1e-5) to known pathogenicity-related genes are listed.
| gname |
phi_molconn_id |
gene_name |
function |
phenotype_of_mutant |
q_start |
q_end |
query_coverage |
subject_coverage |
identity |
evalue |
source pathogen_species |
disease_name |
host_descripton |
Analyzing carbohydrate-active enzyme genes to uncover mechanisms of nutrient degradation
The table lists carbohydrate-active enzyme genes linked to this mutation.
Note: Annotation of carbohydrate-active enzyme genes was performed using CAZy to explore mechanisms of nutrient breakdown and utilization. Genes in plasmid clusters showing strong homology (identity > 70%, subject coverage > 70%, and E-value < 1e−5) to known CAZyme genes are listed.
| gname |
cazy_id |
q_start |
q_end |
query_coverage |
subject_coverage |
identity |
evalue |
Analyzing transport proteins to understand bacterial strategies for substrate uptake and detoxification
The table lists transport proteins linked to this mutation.
Note: Investigation of transport proteins based on TCDB to uncover bacterial mechanisms of substrate transport and environmental detoxification. Genes in plasmid clusters showing strong homology (identity > 70%, subject coverage > 70%, and E-value < 1e−5) to known transport protein entries are listed.
| gname |
tcid |
q_start |
q_end |
query_coverage |
subject_coverage |
identity |
evalue | class_field
class_term |
subclass |
subclass_term |
family |
family_term |
>