Therapeutic Target Identification and Inhibitor Screening against Riboflavin Synthase of Colorectal Cancer Associated Fusobacterium nucleatum

Simple Summary More and more studies are suggesting the role of microbes in several diseases in addition to the germline and environmental factors. F. nucleatum is recently being associated with colorectal cancer and here, we aimed to identify important drug targets from the core genome of colorectal cancer associated F. nucleatum through bioinformatics approach. We used one drug target for further analysis and obtained natural product inhibitors against it. Finally, we validated inhibition stability through dynamics simulation approach. We are hopeful that this study could benefit researchers working on colorectal cancer, its microbiome and cure. Abstract Colorectal cancer (CRC) ranks third among all cancers in terms of prevalence. There is growing evidence that gut microbiota has a role in the development of colorectal cancer. Fusobacterium nucleatum is overrepresented in the gastrointestinal tract and tumor microenvironment of patients with CRC. This suggests the role of F. nucleatum as a potential risk factor in the development of CRC. Hence, we aimed to explore whole genomes of F. nucleatum strains related to CRC to predict potential therapeutic markers through a pan-genome integrated subtractive genomics approach. In the current study, we identified 538 proteins as essential for F. nucleatum survival, 209 non-homologous to a human host, and 12 as drug targets. Eventually, riboflavin synthase (RiS) was selected as a therapeutic target for further processing. Three different inhibitor libraries of lead-like natural products, i.e., cyanobactins (n = 237), streptomycins (n = 607), and marine bacterial secondary metabolites (n = 1226) were screened against it. After the structure-based study, three compounds, i.e., CMNPD3609 (−7.63) > Malyngamide V (−7.03) > ZINC06804365 (−7.01) were prioritized as potential inhibitors of F. nucleatum. Additionally, the stability and flexibility of these compounds bound to RiS were determined via a molecular dynamics simulation of 50 ns. Results revealed the stability of these compounds within the binding pocket, after 5 ns. ADMET profiling showed compounds as drug-like, non-permeable to the blood brain barrier, non-toxic, and HIA permeable. Pan-genomics mediated drug target identification and the virtual screening of inhibitors is the preliminary step towards inhibition of this pathogenic oncobacterium and we suggest mouse model experiments to validate our findings.

[1]  Dokyoon Kim,et al.  Enterotypical Prevotella and three novel bacterial biomarkers in preoperative stool predict the clinical outcome of colorectal cancer , 2022, Microbiome.

[2]  Ying-chao Wang,et al.  Fusobacterium nucleatum stimulates cell proliferation and promotes PD-L1 expression via IFIT1-related signal in colorectal cancer , 2022, Neoplasia.

[3]  S. Bullman,et al.  The cancer chemotherapeutic 5-fluorouracil is a potent Fusobacterium nucleatum inhibitor and its activity is modified by intratumoral microbiota , 2022, Cell reports.

[4]  Ruitao Cha,et al.  Nitroreductase-instructed supramolecular assemblies for microbiome regulation to enhance colorectal cancer treatments , 2022, Science advances.

[5]  Fengming You,et al.  The Role of Fusobacterium nucleatum in Colorectal Cancer Cell Proliferation and Migration , 2022, Cancers.

[6]  Hao Chung The,et al.  Tumour microbiomes and Fusobacterium genomics in Vietnamese colorectal cancer patients , 2022, npj Biofilms and Microbiomes.

[7]  Ling-Hui Li,et al.  Enrichment of Prevotella intermedia in human colorectal cancer and its additive effects with Fusobacterium nucleatum on the malignant transformation of colorectal adenomas , 2022, Journal of Biomedical Science.

[8]  P. Manghi,et al.  Colorectal cancer, Vitamin D and microbiota: A double-blind Phase II randomized trial (ColoViD) in colorectal cancer patients , 2022, Neoplasia.

[9]  S. Verbridge,et al.  Fusobacterium nucleatum induces proliferation and migration in pancreatic cancer cells through host autocrine and paracrine signaling , 2022, Science Signaling.

[10]  Zhezhen Jin,et al.  Circulating IgA Antibodies Against Fusobacterium nucleatum Amyloid Adhesin FadA are a Potential Biomarker for Colorectal Neoplasia , 2022, Cancer research communications.

[11]  M. Neurath,et al.  Rectal Cancer Presenting with Absceding Infection Due to Fusobacterium nucleatum , 2022, Pathogens.

[12]  Yeongmin Kim,et al.  Whole-Transcriptome Sequencing Reveals Characteristics of Cancer Microbiome in Korean Patients with GI Tract Cancer: Fusobacterium nucleatum as a Therapeutic Target , 2022, Microorganisms.

[13]  G. Maulucci,et al.  Proinflammatory and Cancer-Promoting Pathobiont Fusobacterium nucleatum Directly Targets Colorectal Cancer Stem Cells , 2022, Biomolecules.

[14]  R. Uddin,et al.  Mining therapeutic targets from the antibiotic-resistant Campylobacter coli and virtual screening of natural product inhibitors against its riboflavin synthase , 2022, Molecular Diversity.

[15]  H. Qin,et al.  Profiling Fusobacterium infection at high taxonomic resolution reveals lineage-specific correlations in colorectal cancer , 2022, Nature Communications.

[16]  M. Ali,et al.  Unraveling the crystal structure of Leptospira kmetyi riboflavin synthase and computational analyses for potential development of new antibacterials , 2022, Journal of Molecular Structure.

[17]  Julia L. Drewes,et al.  Comparative Analysis of Colon Cancer-Derived Fusobacterium nucleatum Subspecies: Inflammation and Colon Tumorigenesis in Murine Models , 2022, mBio.

[18]  Z. Basharat,et al.  An in silico hierarchal approach for drug candidate mining and validation of natural product inhibitors against pyrimidine biosynthesis enzyme in the antibiotic-resistant Shigella flexneri. , 2022, Infection, genetics and evolution : journal of molecular epidemiology and evolutionary genetics in infectious diseases.

[19]  S. S. Hassan,et al.  Differential analysis of Orientia tsutsugamushi genomes for therapeutic target identification and possible intervention through natural product inhibitor screening , 2021, Comput. Biol. Medicine.

[20]  R. Uddin,et al.  Comparative Metabolic Pathways Analysis and Subtractive Genomics Profiling to Prioritize Potential Drug Targets Against Streptococcus pneumoniae , 2022, Frontiers in Microbiology.

[21]  R. Uddin,et al.  In Silico Study to Identify New Monoamine Oxidase Type A (MAO-A) Selective Inhibitors from Natural Source by Virtual Screening and Molecular Dynamics Simulation , 2021, Journal of Molecular Structure.

[22]  K. Allemailem A Comprehensive Computer Aided Vaccine Design Approach to Propose a Multi-Epitopes Subunit Vaccine against Genus Klebsiella Using Pan-Genomics, Reverse Vaccinology, and Biophysical Techniques , 2021, Vaccines.

[23]  H. Qin,et al.  A newly developed PCR‐based method revealed distinct Fusobacterium nucleatum subspecies infection patterns in colorectal cancer , 2021, Microbial biotechnology.

[24]  M. Jahanzaib,et al.  Therapeutic target identification via differential genome analysis of antibiotic resistant Shigella sonneii and inhibitor evaluation against a selected drug target. , 2021, Infection, genetics and evolution : journal of molecular epidemiology and evolutionary genetics in infectious diseases.

[25]  Lei Zhang,et al.  Malyngamide F Possesses Anti-Inflammatory and Antinociceptive Activity in Rat Models of Inflammation , 2021, Pain research & management.

[26]  I. Choi,et al.  Riboflavin intake, MTRR genetic polymorphism (rs1532268) and gastric cancer risk in a Korean population: a case–control study , 2021, British Journal of Nutrition.

[27]  D. Tondi Novel Targets and Mechanisms in Antimicrobial Drug Discovery , 2021, Antibiotics.

[28]  Michael Y. Galperin,et al.  COG database update: focus on microbial diversity, model organisms, and widespread pathogens , 2020, Nucleic Acids Res..

[29]  Ren Zhang,et al.  DEG 15, an update of the Database of Essential Genes that includes built-in analysis tools , 2020, Nucleic Acids Res..

[30]  I. Khan,et al.  Pan-genomics, drug candidate mining and ADMET profiling of natural product inhibitors screened against Yersinia pseudotuberculosis. , 2020, Genomics.

[31]  N. Rao,et al.  CEG 2.0: an updated database of clusters of essential genes including eukaryotic organisms , 2020, Database J. Biol. Databases Curation.

[32]  A. Almatroudi The Incidence Rate of Colorectal Cancer in Saudi Arabia: An Observational Descriptive Epidemiological Analysis , 2020, International journal of general medicine.

[33]  Joshua J. Levy,et al.  Gradual polyploid genome evolution revealed by pan-genomic analysis of Brachypodium hybridum and its diploid progenitors , 2020, Nature Communications.

[34]  J. Vogel,et al.  Breast cancer colonization by Fusobacterium nucleatum accelerates tumor growth and metastatic progression , 2020, Nature Communications.

[35]  K. Ghaedi,et al.  Signaling pathways involved in colorectal cancer progression , 2019, Cell & Bioscience.

[36]  J. Klaveness,et al.  Towards dual inhibitors of the MET kinase and WNT signaling pathway; design, synthesis and biological evaluation , 2019, RSC advances.

[37]  Z. Qian,et al.  The role of Fusobacterium nucleatum in colorectal cancer: from carcinogenesis to clinical management , 2019, Chronic diseases and translational medicine.

[38]  G. Iraola,et al.  Pathogenomics of Emerging Campylobacter Species , 2019, Clinical Microbiology Reviews.

[39]  Subha Madhavan,et al.  Proteogenomic Analysis of Human Colon Cancer Reveals New Therapeutic Opportunities , 2019, Cell.

[40]  H. R. Bonomi,et al.  A high‐throughput screening for inhibitors of riboflavin synthase identifies novel antimicrobial compounds to treat brucellosis , 2019, The FEBS journal.

[41]  S. Tam,et al.  A Review on the Special Radiotherapy Techniques of Colorectal Cancer , 2019, Front. Oncol..

[42]  D. Raoult,et al.  Genome and pan-genome analysis to classify emerging bacteria , 2019, Biology Direct.

[43]  M. Hossain,et al.  Anti-Inflammatory, Anti-Diabetic, and Anti-Alzheimer’s Effects of Prenylated Flavonoids from Okinawa Propolis: An Investigation by Experimental and Computational Studies , 2018, Molecules.

[44]  A. Jemal,et al.  Global cancer statistics 2018: GLOBOCAN estimates of incidence and mortality worldwide for 36 cancers in 185 countries , 2018, CA: a cancer journal for clinicians.

[45]  Zohar Meir,et al.  Riboflavin and pantothenic acid biosynthesis are crucial for iron homeostasis and virulence in the pathogenic mold Aspergillus fumigatus , 2018, Virulence.

[46]  M. Barile,et al.  The Expression of Riboflavin Transporters in Human Colorectal Cancer. , 2018, Anticancer research.

[47]  David S. Wishart,et al.  DrugBank 5.0: a major update to the DrugBank database for 2018 , 2017, Nucleic Acids Res..

[48]  Donna Neuberg,et al.  Analysis of Fusobacterium persistence and antibiotic response in colorectal cancer , 2017, Science.

[49]  Fangfang Guo,et al.  Fusobacterium nucleatum Promotes Chemoresistance to Colorectal Cancer by Modulating Autophagy , 2017, Cell.

[50]  Olivier Michielin,et al.  SwissADME: a free web tool to evaluate pharmacokinetics, drug-likeness and medicinal chemistry friendliness of small molecules , 2017, Scientific Reports.

[51]  P. Proksch,et al.  Versiquinazolines A-K, Fumiquinazoline-Type Alkaloids from the Gorgonian-Derived Fungus Aspergillus versicolor LZD-14-1. , 2016, Journal of natural products.

[52]  W. Garrett,et al.  Fap2 Mediates Fusobacterium nucleatum Colorectal Adenocarcinoma Enrichment by Binding to Tumor-Expressed Gal-GalNAc. , 2016, Cell host & microbe.

[53]  A. Jemal,et al.  Cancer statistics, 2016 , 2016, CA: a cancer journal for clinicians.

[54]  U. Ribeiro,et al.  High occurrence of Fusobacterium nucleatum and Clostridium difficile in the intestinal microbiota of colorectal carcinoma patients , 2015, Brazilian journal of microbiology : [publication of the Brazilian Society for Microbiology].

[55]  Juan Wu,et al.  A new algorithm for essential proteins identification based on the integration of protein complex co-expression information and edge clustering coefficient , 2015, Int. J. Data Min. Bioinform..

[56]  Douglas E. V. Pires,et al.  pkCSM: Predicting Small-Molecule Pharmacokinetic and Toxicity Properties Using Graph-Based Signatures , 2015, Journal of medicinal chemistry.

[57]  R. Aggarwal,et al.  Proteome mining for drug target identification in Listeria monocytogenes strain EGD-e and structure-based virtual screening of a candidate drug target penicillin binding protein 4. , 2015, Journal of microbiological methods.

[58]  S. Jonjić,et al.  Binding of the Fap2 protein of Fusobacterium nucleatum to human inhibitory receptor TIGIT protects tumors from immune cell attack. , 2015, Immunity.

[59]  R. Peek,et al.  Gastrointestinal malignancy and the microbiome. , 2014, Gastroenterology.

[60]  M. Ebert,et al.  Fusobacterium nucleatum associates with stages of colorectal neoplasia development, colorectal cancer and disease outcome , 2014, European Journal of Clinical Microbiology & Infectious Diseases.

[61]  T. Keku,et al.  Fusobacterium spp. and colorectal cancer: cause or consequence? , 2013, Trends in microbiology.

[62]  M. Meyerson,et al.  Fusobacterium nucleatum potentiates intestinal tumorigenesis and modulates the tumor-immune microenvironment. , 2013, Cell host & microbe.

[63]  Peter M. Kasson,et al.  GROMACS 4.5: a high-throughput and highly parallel open source molecular simulation toolkit , 2013, Bioinform..

[64]  B. Shanmugham,et al.  Identification and Characterization of Potential Therapeutic Candidates in Emerging Human Pathogen Mycobacterium abscessus: A Novel Hierarchical In Silico Approach , 2013, PloS one.

[65]  Martha L Slattery,et al.  MAP kinase genes and colon and rectal cancer. , 2012, Carcinogenesis.

[66]  Pascal Braun,et al.  History of protein–protein interactions: From egg‐white to complex networks , 2012, Proteomics.

[67]  Richard A. Moore,et al.  Fusobacterium nucleatum infection is prevalent in human colorectal carcinoma. , 2012, Genome research.

[68]  Jian Yang,et al.  VFDB 2012 update: toward the genetic diversity and molecular evolution of bacterial virulence factors , 2011, Nucleic Acids Res..

[69]  Jianping Xie,et al.  Riboflavin Biosynthetic and Regulatory Factors as Potential Novel Anti‐Infective Drug Targets , 2010, Chemical biology & drug design.

[70]  Aidong Zhang,et al.  Protein Interaction Networks: Computational Analysis , 2009 .

[71]  Torsten Schwede,et al.  The SWISS-MODEL Repository and associated resources , 2008, Nucleic Acids Res..

[72]  Mark Johnson,et al.  NCBI BLAST: a better web interface , 2008, Nucleic Acids Res..

[73]  Jaideep P. Sundaram,et al.  Genome analysis of multiple pathogenic isolates of Streptococcus agalactiae: implications for the microbial "pan-genome". , 2005, Proceedings of the National Academy of Sciences of the United States of America.

[74]  Robert C. Edgar,et al.  MUSCLE: multiple sequence alignment with high accuracy and high throughput. , 2004, Nucleic acids research.

[75]  K. Kinzler,et al.  The multistep nature of cancer. , 1993, Trends in genetics : TIG.

[76]  N. Dubrawsky Cancer statistics , 1989, CA: a cancer journal for clinicians.