Rapacious Bacteria and Their Growth Mechanism in Living Cells

Introduction

In a laboratory encounter between two cells of bacteria: a vibrio coralliilyticus, a large rod-shaped marine microbe, and a very small microbe, Halo bacterio vorax, the tiny microbe grabbed the larger bacteria. In a lengthy report published on the New York Times website on August 25, the writer “Catherine J. Wu” deals with this confrontation that took place in an American academic laboratory [1].

Rapacious bacteria: The researchers say that the desperate Vibrio bacteria sought to get rid of their attacker, writhing and spinning in a pool of liquid, meandering in the absurd before finally reaching a “glaring stop” as described by Dr. Laura Williams, a microbiologist at Florida A&M University. Then the halo bacteria got their act together: piercing the outside of the vibrio and beginning to penetrate the inner cavity, where it would sink into the guts of its host, replicating itself several times and set off freely to find its next meal. These Rapacious bacteria hold tremendous promise of remarkable practical applications [2]. They can help people overcome harmful microbes in the environment, or cleanse pathogens from the food supply. Some experts believe it could one day serve as a kind of live treatment, helping to remove drugresistant germs from patients for whom all other treatments have failed [3,4]. To use this group of microbes as a live antibiotic, “we need to know how it grows [because] we can’t use it if we don’t understand it,” says Terence Sacchi, a microbiologist who studies Rapacious bacteria at Belgium’s de Duve Institute [5-8].

Proliferation of Predacious Bacteria

Some predatory bacteria are capable of eating dozens or even hundreds of bacterial species, enabling them to thrive in most habitats. While phages work quickly, within hours, predatory bacteria multiply, sometimes taking weeks to grow in the lab. However, its predatory lifestyle is so productive that it seems to have evolved more than once. Overall, predatory bacteria are “very effective killing machines,” says Daniel Kaddouri, a microbiologist at Rotgers University who has studied predatory bacteria since 2003 [9-12]. Predatory bacteria are not exclusively weapons of destruction. In Germany, Dr. Jonke is working on a series of projects that highlight the peacemaking skills of microbes in the complex community of bacteria that live in the gut [13]. She says some evidence suggests that “healthy humans usually have predatory bacteria” as part of the naturally coexisting bacterial community. She added that little is understood about her role. But you’ll probably keep order in the gut and ensure no one goes out of style. Dr. Jonke’s work suggests that people with digestive disorders may have lost this delicate balance. Reintroduction of predatory bacteria into the human body’s bacterial system may help restore it [14-20]. “In my ideal world, we could use predatory piercing bacteria as a kind of microorganism,” Junki said. It is also possible that a similar dynamic will be used in nature, where Dr. Williams has turned most of her attention to this, as even trace amounts of predacious bacteria can completely reorganize the microbial organelles of a sample of seawater. Some types of bacteria kill and then consume other microorganisms, and these types are called predatory bacteria [21- 25]. This type includes organisms such as M. xanthus, which form swarms of cells that kill and engulf any bacteria they encounter. Another type of predatory bacteria attaches itself to its prey, digests it, sucks nutrients from it like sucking insects, or invades another cell and multiplies within the Daptobacter cytosol. It is believed that these predatory bacteria evolved by ingesting scavengers that consumed dead microorganisms through adaptations that allowed them to entrap and kill other organisms.

Certain bacteria form closed spatial assemblies and are essential for their survival [26-30]. One such mutualistic grouping, called interspecific hydrogen transfer, occurs between groups of anaerobic bacteria that consume organic acids such as butyric acid or propionic acid and produce hydrogen, and methanogenic archaea that consume hydrogen [31-35]. Bacteria in this community are unable to consume organic acids as the reaction and produce hydrogen that accumulates in the surrounding environment. The hydrogen concentration is kept low enough to allow bacteria to grow only if there is a strong bond with the hydrogen-consuming archaea [36-40]. In the soil, the microorganisms present in the root zone (the area that includes the surface of the root and the soil that holds the root after gently shaking it) carry the fixation of exogenous nitrogen and the conversion of nitrogen gas into nitrogenous compounds [41,42]. This works to make it easier for many plants to absorb nitrogen that they cannot fix nitrogen themselves [43- 46]. Many other types of bacteria are found coexisting in humans and other living organisms, for example, there can be more than 1000 types of bacteria in the body’s natural intestinal flora in the human intestine, which increases the immunity of the intestine, and also manufactures vitamins such as folic acid and vitamin K and biotin convert sugar into lactic acid (see Lactobacillus), plus they ferment whole carbohydrates.The presence of the gut flora in the intestine inhibits the growth of pathogenic bacteria (usually through competitive exclusion) and thus beneficial bacteria are sold as nutritional supplements and probiotics [47-50].

The effect of Predacious Bacteria on the immune System

In animal studies, predacious bacteria have shown promising results in targeting disease-causing germs such as salmonella and Yersinia pestis that cause plague. Dr. Kaddouri and Nancy Connell, a microbial geneticist at the Johns Hopkins Center for Health Security, administered a dose of the bacterium Bdellovibrios into the lungs of rats and mice, and watched them devour most of the prey. The predacious bacteria are not interested in the non-microbial cells, and they do not appear to provoke the immune system even when placed directly on the surface of the rabbit’s eyeball [51-54]. Dr. says. Kaddouri says this indicates that these microbes can be safe for use in humans, as “we have pushed a lot of predacious bacteria into animals and have never seen an aggressive immune response.” But these predacious thrive only in the presence of their prey, so they usually struggle to conquer entire populations of microbes on their own. Being microbes, they are eventually removed from the body by immune cells, which “have absolutely no defense,” Dr. Connell said. As a result, predacious bacteria are not strong candidates for treating infections that have already spread throughout the body [55]. However, predacious bacteria, when managed the right way, may be persuaded to act in concert with the immune response to eliminate their targets. They can also be combined with another treatment such as an antibiotic or even a low dose of phages. Dr. says. Kaddouri “We need to start thinking about comprehensive methods. It’s another tool in the arsenal” [56-59].

Bacterial Cultures in Laboratories

One of the most well-known predatory bacteria is Bdellovibrio bacteriovorus, which preys on the victim bacteria, by implanting itself between the inner and outer cell membranes of the host, and then begins to multiply. Bdellovibrio bacteriovorus has not been known to cause disease in humans, but it is a known pathogen of Gram-negative bacteria, making it a potential biological control option for many human pathogens. Among the contributions of these bacteria in the field of biotechnology is their use in some water treatment plants to reduce the proliferation of Gram-negative bacteria in water. In agricultural terms, it has been used to reduce the spread of plant pathogens in some crops. It should be noted that the use of (Bdellovibrio bacteriovorus) in agriculture requires extensive knowledge of the crop and its environment, because it may attack some types of Gram-negative bacteria such as (rhizobacterias) necessary to promote the growth of some crops. Another species of predatory bacteria is Micavibrio aeruginosavorus, which, unlike Bdellovibrio bacteriovorus, does not immerse itself in the space between the inner and outer cell membranes of the host, but rather preys on it by attaching to its surface, then behaves like a vampire, killing it after filtering its fluids (leaching) [60]. Micavibrio aeruginosavorus has shown superior abilities to kill bacteria in the form of cell membranes (biofilms), which are more than a thousand times more resistant to antibiotics and antiseptics than microbes in their single form. Bacteria often function as a group of multiple cells known as biofilms, exchange a variety of molecular signals for internal communication between cells, and are preoccupied with regulating multicellular behavior. General benefits of multicellular cooperation include cell division to function, access to resources that it cannot be utilized efficiently by monocytes, collective defense against adversaries, and finally, improved population presence by offshoring and the creation of distinct and different cell types [61- 63]. For example, bacteria in biofilms can resist 500 times more germs than individual planktonic bacteria of the same species. One type of intercellular communication by molecular signaling is called quorum sensing or quorum detection, which provides the reason for determining whether or not the local population density is present (which is high enough for production and investment in procedures or processes that only succeed if a large number of the same organisms act in the same manner only, as in secreting digestive enzymes) or emitting light. Quorum detection allows bacteria to coordinate gene expression, production, editing, and detection (self-inferred) or pheromones that accumulate with growth in cell proliferation [64] (Figure1).

Figure 1: Demonstrates the attack of predacious bacteria on Pseudomonas bacteria.

Conclusions

The predacious properties of Micavibrio aeruginosavorus have contributed to it being considered a live antibiotic. Predatory bacteria also have contributions to combating food-borne pathogens (Foodbrone pathogens), one study reported that Bdellovibrio bacteriovorus was successful in combating Escherichia coli O157:H7 and some types of Salmonella (Salmonella spp). found on stainless steel surfaces, which indicates the possibility of exploiting predatory bacteria in automated food processing and production systems, especially after these bacteria showed their ability to attack bacteria in the form of cell membranes, which are known to be difficult to get rid of by traditional methods, in addition to Being a contributing factor to the outbreak of foodborne diseases, through cross contamination, which usually occurs when food passes through contaminated surfaces, this type of contamination is often observed in automated food processing and production systems.

References

• Witte W (2004) International dissemination of antibiotic resistant strains of bacterial pathogens. Infect Genet Evol 4(3): 187-191.
• Vardiman JW, Thiele J, Arber, Daniel A Arber, Richard D Brunning, et al. (2009) The 2008 revision of the World Health Organization (WHO) classification of myeloid neoplasms and acute leukemia: rationale and important changes. Blood 114(5): 937-951.
• Nagham Mahmood Aljamali (2016) Synthesis and Biological Study of Hetero (Atoms and Cycles) Compounds. Der Pharma Chemica 8(6): 40-48.
• Alecsandru Ioan Baba, Cornel Cătoi (2007) Comparative oncology. Bucharest: The Publishing House of the Romanian Academy 973(27): 1457-1463.
• Nagham Mahmood Aljamali (2021) Inventing of Macrocyclic Formazan Compounds and Studying Them Against Breast Cancer for the first Time Globally. Annals of pharma research 9(7): 525-533.
• Nagham Mahmood Aljamali (2021) Creation of Innovated Macrocyclic Sulfazan-Formazan Compounds and Linear Sulfazan-Formazan for the first Time Globally with their Assay as Antifungal. Biomedical Journal of Scientific & Technical Research 40(3): 32266-32272.
• Nagham Mahmood Aljamali, S Jawad (2022) Preparation, Spectral Characterization, Thermal Study, and Antifungal Assay of (Formazane -Mefenamic acid)- Derivatives. Egyptian Journal of Chemistry 65(2).
• Nagham Mahmood Aljamali (2017) Synthesis of Antifungal Chemical Compounds from Fluconazole with (Pharma-Chemical) Studying. Research journal of Pharmaceutical, biological and chemical sciences 8(3): 564 -573.
• Andersson DI (2006) The biological cost of mutational antibiotic resistance: any practical conclusions? Curr Opin Microbiol 9(5): 461-465.
• Nagham Mahmood Aljamali (2019) Review on (Azo, Formazane, Sulfazane)-Compounds. International Journal of Innovations in Scientific Engineering 10: 19-45.
• Nagham Mahmood Aljamali (2020) Alternative Methods in Organic Synthesis. 1st Edition. Eliva Press SRL: Europe.
• Larson E (2007) Community factors in the development of antibiotic resistance. Annu Rev Public Health 28: 435-447.
• Nagham Mahmood Aljamali, Imd Kam (2020) Development of Trimethoprim Drug and Innovation of Sulfazane-Trimethoprim Derivatives as Anticancer Agents. Biomedical & Pharmacology Journal 13(2): 613-625.
• Imd Krm, Hasaneen Kudhair Abdullabass, Nagham Mahmood Aljamali (2020) Invention of (Gluta. Sulfazane-Cefixime) Compounds as Inhibitors of Cancerous Tumors. Journal of Cardiovascular Disease Research 11(2): 44-55.
• Matheus ME, De Almeida Violante F, Garden SJ, Angelo C Pinto, Patricia Dias Fernandes (2007) Isatins inhibit cyclooxygenase-2 and inducible nitric oxide synthase in a mouse macrophage cell line. Eur J Pharmacol 556(1-3): 200-206.
• Mid Mohmd, Nagham Mahmood Aljamali, Sabreen Ali Abdalrahman (2018) Formation of Oxadiazole Derivatives Ligands from Condensation and Imination Reaction with References to Spectral Investigation, Thermal and Microbial Assay. Biochem Cell Arch 18(1): 847-853.
• Nagham Mahmood Aljamali (2015) Review in Azo Compounds and its Biological Activity. Biochem Anal Biochem 4(2): 169.
• Abdmajed MN, Nagham Mahmood Aljamali (2021) Preparation of Benzothiazole-Formazane Reagents and Studying of (Spectral, Thermal, Scanning Microscopy, Biological Evaluation). International Journal of Pharmaceutical Research 13(1): 4290-4300.
• Mad M, Nagham Mahmood Aljamali, Nadheema A A (2018) Preparation, Spectral Investigation, Thermal Analysis, Biochemical Studying of New (Oxadiazole -Five Membered Ring)-Ligands. Journal of Global Pharmacy Technology 10(1): 20-29.
• Hasneen Kudhair Abdullabass, Aseel Mahmood Jawad, Nagham Mahmood Aljamali (2020) Synthesis of drugs derivatives as inhibitors of cancerous cells. Biochem Cell Arch 20(2): 5315-5322.
• Aseel Mahmood Jawad, Nagham Mahmood Aljamali (2020) Innovation, Preparation of Cephalexin Drug Derivatives and Studying of (Toxicity & Resistance of Infection). International Journal of Psychosocial Rehabilitation 24(4): 3754-3767.
• Hussein Hmed, Nagham Mahmood Aljamali (2021) Preparation, Characterization, Antibacterial Study, Toxicity Study of New Phenylene diamine- Formazan Derivatives. Indian Journal of Forensic Medicine & Toxicology 15(2): 3102-3112.
• Nagham Mahmood Aljamali, Husin Mebl Azez (2021) Synthesis and Characterization of Some New Formazan - Cefixime and Study of Against Breast Cancer Cells. Annals of the Romanian Society for Cell Biology 25(4): 8562-8578.
• Nagham Mahmood Aljamali, Asmaa Kefah Mahdi (2021) Synthesis, Identification and Anticancer Studying of Heterocyclic- Mefenamic Drug via Thiosemicarbazide. Annals of the Romanian Society for Cell Biology 25(4): 8521-8537.
• F Jawad, Nagham Mahmood Aljamali (2021) Preparation, Investigation and Study of Biological Applications of Tyrosine Derivatives against Breast Cancer Cells. NeuroQuantology 19(9): 117-125.
• Nagham Mahmood Aljamali (2015) Intisar Obaid Alfatlawi. Synthesis of Sulfur Heterocyclic Compounds and Study of Expected Biological Activity Research. J Pharm and Tech 8(9): 1225-1242.
• Intisar Obaid Alfatlawi, Nuha S S, Zainab M J, Nagham Mahmood Aljamali (2017) Synthesis of New Organic Compounds Via Three Components Reaction with Studying of (Identification, Thermal Behavior, Bioactivity on Bacteria of Teeth). Journal of Global Pharma Technology 11(9): 157-164.
• Nagham Mahmood Aljamali, Saher Mahmood Jawd, Zainab M J, Intisar Obaid Alfatlawi (2017) Inhibition activity of (Azo-acetyl acetone) on bacteria of mouth. Research Journal of Pharmacy and Technology 10(6): 1683-1686.
• Aseel Mahmood Jawad, Nagham Mahmood Aljamali, Saher Mahmood Jawd (2020) Development and Preparation of ciprofloxacin Drug Derivatives for Treatment of Microbial Contamination in Hospitals and Environment. Indian Journal of Forensic Medicine & Toxicology 14(2): 1115-1122.
• Shireen R Rasool, Nagham Mahmood Aljamali, Ali Jassim Al Zuhairi (2020) Guanine substituted heterocyclic derivatives as bioactive compounds. Biochem Cell Arch 20: 3651-3655.
• Deniz Ar, Alexander F R Kilpatrick, Beatrice Cula, Christian Herwig, Christian Limberg (2021) Transformation of Formazanate at Nickel (II) Centers to Give a Singly Reduced Nickel Complex with Azoiminate Radical Ligands and Its Reactivity toward Dioxygen. Inorganic Chemistry 60(18): 13844-13853.
• Francesca Milocco, Folkert de Vries (2021) Widening the Window of Spin-Crossover Temperatur in Bis (formazanate). Inorganic Chemistry 60(3): 2045-2055.
• Abd Ali H, Nagham Mahmood Aljamali (2021) Chalcone-Heterocyclic Derivatives (Synthesis, Spectral Identification, Microbial Evaluation). International Journal of Pharmaceutical Research 13(1): 4234-4242.
• Nor A, Sud S, Nagham Mahmood Aljamali (2019) Synthesis, Characterization and Thermal Analysis for New Amoxil Ligands. Asian Journal of Chemistry 31(5): 1022-1026.
• Rajaa Abdul Ameer Ghafil, Nor A Alrab, Nagham Mahmood Aljamali (2020) Synthesis of Triazole Derivatives via Multi Components Reaction and Studying of (Organic Characterization, Chromatographic Behavior, Chem-Physical Properties). Egyptian Journal of Chemistry 63(11): 4163 - 4174.
• Nagham Mahmood Aljamali (2018) (Synthesis, Investigation, Chromatography, Thermal)- Behavior of (Five, Seven)- Membered Ring with Azo and Anil Compounds. Pak J Biotechnol 15(1): 219-239.
• Thomadsen Bruce, Nath Ravinder, Fred B Bateman, Jonathan Farr, Cal G, et al. (2014) Potential Hazard Due to Induced Radioactivity Secondary to Radiotherapy. Health Physics 107(5): 442-460.
• Shapira T, Pereg D, Lishner M (2008) How I treat acute and chronic leukemia in pregnancy. Blood Rev 22(5): 247-259.
• Mhamd Abl, Abd Ali, Nagham Mahmood Aljamali (2021) Synthesis, Spectral, Bioassay, Chromatographic - Studying of New Imidazole Reagents via Three Components Reaction. NeuroQuantology 19(7): 115-122.
• Nagham Mahmood Aljamali, Jad F (2021) Preparation, Diagnosis and Evaluation of Cyclic-Tryptophan Derivatives as Anti Breast Cancer Agents. Biomed Pharmacol J. 2021: 14(4).
• Kanavy HE, Gerstenblith MR (2001) Ultraviolet radiation and melanoma. Semin Cutan Med Surg 30(4): 222-228.
• Burnett ME, Wang SQ (2011) Current sunscreen controversies: a critical review. Photodermatol Photoimmunol Photomed 27(2): 58-67.
• Kütting B, Drexler H (2010) UV-induced skin cancer at workplace and evidence-based prevention. Int Arch Occup Environ Health 83(8): 843-854.
• Balk SJ (2011) Ultraviolet radiation: a hazard to children and adolescents. Pediatrics 127(3): 588-597.
• Lin JS, Eder, M Weinmann S (2011) Behavioral counseling to prevent skin cancer: a systematic review for the U.S. Preventive Services Task Force. Annals of internal medicine154(3): 190-201.
• Nagham Mahmood Aljamali, Aseel Mahmood Jawad, Imd Kam (2020) Public Health in Hospitals. 1 First Edition. Eliva Press: Europe.
• Catherine de Martel, Damien Georges, Freddie Bray, Jacques Ferlay, Gary M Clifford (2020) Global burden of cancer attributable to infections in 2018: a worldwide incidence analysis. Lancet Glob Health 8(2): e180-e190.
• Asmaa Kefah Mahdi, Nagham Mahmood Aljamali (2020) Heterocyclic- Derivatives with Aspirin Drug (Synthesis, Characterization, Studying of Its Effect on Cancer Cells). International Journal of Cell Biology and Cellular Processes 6(2): 30-37.
• Wild CP, Weiderpass E, Stewart BW (2020) World Cancer Report: Cancer Research for Cancer Prevention. Lyon: International Agency for Research on Cancer.
• Stacy Haverstick, Cara Goodrich, Regi Freeman, Shandra James, Rajkiran Kullar (2017) Patients' Hand Washing and Reducing Hospital-Acquired Infection. Critical Care Nurse 37(3): e1-e8.
• Molins, Ricardo A Wiley-IEEE (2001) 23.
• Diehl JF (2002) Food irradiation—past, present and future". Radiation Physics and Chemistry 63(3-6): 211-215.
• Nagham Mahmood Aljamali (2022) Designation of Macrocyclic Sulfazan and Triazan as Innovated Compounds with Their Estimation in Nano-Activities by the Scanning Microscope. International Journal of Convergence in Healthcare 2(1): 25-34.
• Nagham Mahmood Aljamali (2022) Origination of Macrocyclic Formazan with Macrocyclic Sulfazan and Triazan as Innovated Compounds and Compared Their efficiency Against Breast Cancer. Open Access Journal of Biomedical Science 4(1).
• Nagham Mahmood Aljamali (2021) Synthesis Innovative Cyclic Formazan Compounds for the First Time and Evaluation of Their Biological Activity. International Journal of Polymer Science & Engineering 7(2): 5-14.
• Nagham Mahmood Aljamali (2022) Inventing of Macrocyclic Formazan Compounds with Their Evaluation in Nano- Behavior in the Scanning Microscope and Chromatography. Biomedical Journal of Scientific & Technical Research 41(3): 32783-32792
• Aman WA, Weber DJ (2004) Disinfection in Health Care Facilities: What Clinicians Need to Know. Clinical Infectious Diseases 39(7): 700-709.
• William A Rutala, Weber David J (2010) Guideline for disinfection and sterilization cal instruments. Infection Control and Hospital Epidemiology 31(2): 107-117.
• Roth S, Feichtinger J,Hertel C (2010) Characterization of Bacillus subtilisspore inactivation in low-pressure, low-temperature gas plasma sterilization processes. Journal of Applied Microbiology 108(2): 521-531.
• Kanemitsu Keiji, Imasaka Takayuki, Ishikawa Shiho, Hiroyuki Kunishima, Hideo Harigae, et al. (2005) A Comparative Study of Ethylene Oxide Gas, Hydrogen Peroxide Gas Plasma, and Low-Temperature Steam Formaldehyde. Infection Control & Hospital Epidemiology 26(5): 486-489.
• Mushtaq Maryam, Banks Charles J, Heaven Sonia (2012) Effectiveness of pressurised carbon dioxide for inactivation of Escherichia coli isolated from sewage sludge. Water Science and Technology 65(10): 1759-1764.
• Nagham Mahmood Aljamali, Aliaa HM, Maryam JN (2022) Review on Analysis of Breast Tumor with Methods of Treatment. Open Access Journal of Biomedical Science 4(1): 1580-1586.
• McDonnell Gerald, Burke Peter (2003) The Challenge of Prion Decontamination. Clinical Infectious Diseases 36(9): 1152-1154.
• C Rogez Kreuz, R Yousfi, C Soufflet, I Quadrio, Z X Yan, et al. (2009) Inactivation of Animal and Human Prions by Hydrogen Peroxide Gas Plasma Sterilization. Infection Control & Hospital Epidemiology 30(8): 769-777.