Pseudomonas putida bacteria: the biotech industry's obsession with the organism's fundamental carbon and cellular biochemistry

Title

Pseudomonas putida bacteria: the biotech industry's obsession with the organism's fundamental carbon and cellular biochemistry

Author

1. Ahmed Nabawy, Student, Darrang College, Tezpur, India

Abstract

Pseudomonas putida, a rod-shaped microorganism that belongs to the genus Negative bacteria, is very adaptable. Their metabolism has developed to cope with environmental and chemical stress, allowing them to live and even flourish under extreme conditions. This quality allows it to survive even in harsh environments. Research into the bacterium's potential industrial uses has so intensified in recent years. Other important factors are the use of waste materials and inexpensive natural biomass substrate to create value-added compounds. This progress is being driven by systems bioinformatics, which combines systems genetic analysis techniques with new fission reactors and renewable biomaterials. Systems genomics is one factor fueling this development.

Keywords

Conclusion

The product line of P. putida, like those of many industrialized microorganisms, has undergone significant evolution in recent times. The high genetic openness and inherent resistance it has seem to be advantageous for coping with the poisonous and harsh conditions involved with industrial bioprocessing and the de-novo creation of often synthetic chemicals. It's important to remember that this versatile bacterium is employed in a wide range of industrial biotechnology processes. P. putida is a key player in the industrial manufacture of chiral compounds because to its diverse enzyme repertory. Potential for P. putida's use to expand in industrial biotechnology is high because of the exciting new products that are becoming accessible thanks to the proliferation of efficient P. putida cellular factory. P. putida pipes that use renewable hydrocarbons or industrial effluent for sustainability bio-production are pictured, and such an integration might be an exciting future development. P. putida's vast intrinsic route repertory allows it to breakdown and metabolise a wide variety of compounds, including sophisticated aromatic hydrocarbons.

P. putida is capable of utilising such substrates, therefore it might potentially convert aromatic chemicals present in lignocellulose from fast pyrolysis into value-added products like cis-cis muconate, a great starting material for the production of adipic acid. In addition to its potential utility in the sugar industry, P. putida shows promise as a tool for creating novel compounds or materials. P. putida's high resistance to environmental hazards, along with its amenability to genetic engineering, makes it a promising candidate for use as a platform for producing otherwise unattainable synthetic chemicals. Experimental and analytical systems level approaches will be necessary to decipher the intricacy of the central and peripheral biosynthetic processes in P. putida and regulate them. Through methods like fine-tuning expression and managing gene regulation or integrating complex allogeneic pathways, tissue engineering will allow for a new level of ductility in redesigning metabolism for greater bio-production. P. putida has a bright future thanks to the combination of rational strained engineering and revolutionary concepts or genetic engineering, which will lead to strains with even better tolerance to specific operating conditions and more widespread use in industry.

Author Contrubution

The author confirms sole responsibility for the following: study conception and design, data collection, analysis and interpretation of results, and manuscript preparation.

Funding

The authors did not receive any specific grants from funding agencies in the public, commercial, or non-profit sectors for the research, authorship, and/or publication of this article.

Conflict of Interest

All authors declare that they have no conflicts of interest.

Data Sharing Statement

Not applicable

Software And Tools Use

Not applicable

Acknowledgements

I thank the following individuals for their expertise and assistance in all aspects of our study and for their help in writing the manuscript. I am also grateful for the insightful comments given by anonymous peer reviewers. Everyone's generosity and expertise have improved this study in myriad ways and saved me from many errors.