Bacterial Cell Division: Discovering how it begins and the network of protein interactions it requires. All cells must coordinate cell division with chromosome replication to ensure that the DNA is partitioned equally into newborn cells. We will establish the defect of a novel mutant blocked in the earliest stage of cell division in bacteria to obtain unique information about this vital regulatory step. We will use our newly discovered protein interaction network to establish what role protein i ....Bacterial Cell Division: Discovering how it begins and the network of protein interactions it requires. All cells must coordinate cell division with chromosome replication to ensure that the DNA is partitioned equally into newborn cells. We will establish the defect of a novel mutant blocked in the earliest stage of cell division in bacteria to obtain unique information about this vital regulatory step. We will use our newly discovered protein interaction network to establish what role protein interactions play in integrating cell division with other biological pathways in the cell to ensure its tight regulation. Our discoveries will facilitate the design of new antibiotics that target cell division to fight antibiotic-resistant bacteria and bioterrorism organisms.Read moreRead less
Establishing how bacterial cells position the division site. Cell division is essential for life. It is required for bacterial infections and, if uncontrolled, causes diseases such as cancer. We will establish how bacterial cells position the division site precisely to ensure faithful production of newborn cells. We will use the latest technology in bacterial cell biology to provide novel, clear-cut information to maintain Australia at the leading edge of this important area of research. There i ....Establishing how bacterial cells position the division site. Cell division is essential for life. It is required for bacterial infections and, if uncontrolled, causes diseases such as cancer. We will establish how bacterial cells position the division site precisely to ensure faithful production of newborn cells. We will use the latest technology in bacterial cell biology to provide novel, clear-cut information to maintain Australia at the leading edge of this important area of research. There is an alarming increase in antibiotic resistant bacteria and an imminent threat of bioterrorism. This research allows the opportunity for the development of new antibiotics to protect Australia protected from these dangerous bacteria. Read moreRead less
Regulating the earliest step in bacterial cell division: Z ring assembly. Cell division is essential for survival. What are the cues that signal cells to divide at the right place and at the right time? How do cells ensure that when division occurs to produce two newborn cells, each one receives the correct amount of DNA? The answers to these questions are essential to understand how organisms reproduce and grow. But they remain unknown. This research addresses these questions in bacteria. Our d ....Regulating the earliest step in bacterial cell division: Z ring assembly. Cell division is essential for survival. What are the cues that signal cells to divide at the right place and at the right time? How do cells ensure that when division occurs to produce two newborn cells, each one receives the correct amount of DNA? The answers to these questions are essential to understand how organisms reproduce and grow. But they remain unknown. This research addresses these questions in bacteria. Our discoveries will have a significant impact on our understanding of the regulation of this vital process and will facilitate the design of novel antibiotics that target it.Read moreRead less
Bacterial Proteomics: From Cell Division to Novel Antibiotic Targets. When a cell divides it is essential that each newborn cell gets a complete copy of the DNA. To ensure that this happens, cell division must be tightly controlled. It is not known how this occurs in bacteria. However, if we knew what molecules were involved in this control, we could target them to kill harmful bacteria. This project aims to identify such regulatory molecules as candidate targets for antimicrobial agents, with a ....Bacterial Proteomics: From Cell Division to Novel Antibiotic Targets. When a cell divides it is essential that each newborn cell gets a complete copy of the DNA. To ensure that this happens, cell division must be tightly controlled. It is not known how this occurs in bacteria. However, if we knew what molecules were involved in this control, we could target them to kill harmful bacteria. This project aims to identify such regulatory molecules as candidate targets for antimicrobial agents, with a view to developing powerful, novel antibiotics to protect us from the imminent threat of bioterrorism and antibiotic-resistant bacteria.
Read moreRead less
Bacterial filamentation as a survival strategy: a goldmine for the discovery of new cell division regulators. The increasing emergence of untreatable bacterial infections is a serious threat to the health of Australians. Medical advances (organ transplants, chemotherapy), increases in diabetes, and an aging population increase the risk of infections caused by bacteria that are now resistant to most available antibiotics. New classes of antibiotics are urgently needed to treat these infections. T ....Bacterial filamentation as a survival strategy: a goldmine for the discovery of new cell division regulators. The increasing emergence of untreatable bacterial infections is a serious threat to the health of Australians. Medical advances (organ transplants, chemotherapy), increases in diabetes, and an aging population increase the risk of infections caused by bacteria that are now resistant to most available antibiotics. New classes of antibiotics are urgently needed to treat these infections. This project uses a novel approach to identify the mechanisms bacterial cells use to control their growth and avoid attack by our immune system. The research will identify potential targets for the development of new, effective antibiotics to kill multi-resistant bacteria, and ensure Australia's position at the forefront of infection control.Read moreRead less
Stuctural analysis of RNA polymerase elongation complexes. RNA polymerase (RNAP) is an essential enzyme in all living cells. Its role is to convert the genetic information stored in genes into a message that can be converted into protein. Many additional factors are required to ensure that this enzyme functions correctly in the cell. The aim of this project is to obtain structural information on a bacterial RNAP complexed with an essential transcription factor called NusA. Using this information ....Stuctural analysis of RNA polymerase elongation complexes. RNA polymerase (RNAP) is an essential enzyme in all living cells. Its role is to convert the genetic information stored in genes into a message that can be converted into protein. Many additional factors are required to ensure that this enzyme functions correctly in the cell. The aim of this project is to obtain structural information on a bacterial RNAP complexed with an essential transcription factor called NusA. Using this information, plus data already obtained on the structure of this enzyme complexed with another essential factor called sigma, we will design small molecules to inhibit the interaction of these essential factors with polymerase. These molecules will serve as leads for the development of new antibiotics.Read moreRead less
Investigating the Ability of Honey to Inhibit Bacterial Biofilms Found in Chronic Wounds. Chronic (non-healing) wounds are a serious health problem in Australia. One quarter of our institutionalized aged population have pressure ulcers. The difficulty in treating these wounds is that most contain communities of bacteria, called biofilms, that are not killed by conventional antibiotics. Special honeys from Australia and NZ that are effective in chronic wound treatment can eradicate these biofilms ....Investigating the Ability of Honey to Inhibit Bacterial Biofilms Found in Chronic Wounds. Chronic (non-healing) wounds are a serious health problem in Australia. One quarter of our institutionalized aged population have pressure ulcers. The difficulty in treating these wounds is that most contain communities of bacteria, called biofilms, that are not killed by conventional antibiotics. Special honeys from Australia and NZ that are effective in chronic wound treatment can eradicate these biofilms. This project will identify the components in honey that do this and determine how they do it, to provide a more effective chronic wound treatment. It will decrease the prevalence of these wounds in Australia and the associated personal trauma and health costs.Read moreRead less
The Fine Tuned Physiology of Microaerophilic Gastric Spirilla. The aim of the project is to understand the molecular basis of fundamental properties of the physiology of enterogastric spiral bacteria of the genera Campylobacter and Helicobacter. The characteristics of these obligate microaerophiles which will be investigated are their aerobic respiratory chains, the special metabolites and enzymes involved in thiol-disulphide redox balance, and their essential requirement for carbon dioxide. Mic ....The Fine Tuned Physiology of Microaerophilic Gastric Spirilla. The aim of the project is to understand the molecular basis of fundamental properties of the physiology of enterogastric spiral bacteria of the genera Campylobacter and Helicobacter. The characteristics of these obligate microaerophiles which will be investigated are their aerobic respiratory chains, the special metabolites and enzymes involved in thiol-disulphide redox balance, and their essential requirement for carbon dioxide. Microaerobes include some bacteria, archea and protozoa. Realisation of the widespread habitats and importance of microaerophiles, has led recently to a vigorous interest in understanding their physiology. Knowledge of the basic properties of microaerophily has potential applications to Environmental Microbiology, Agriculture, Industrial Microbiology, Veterinary Science and Medicine.Read moreRead less
Structural analysis and functional inactivation of bacterial transcription complexes. RNA polymerase is an essential enzyme in all living cells. Its role is to convert the genetic information stored in genes into a message that can be converted into protein. As such, the bacterial RNA polymerase represents an ideal target for the development of new antibiotics which will be important in maintaining the health of the Australian community and also in protecting the community from the very real thr ....Structural analysis and functional inactivation of bacterial transcription complexes. RNA polymerase is an essential enzyme in all living cells. Its role is to convert the genetic information stored in genes into a message that can be converted into protein. As such, the bacterial RNA polymerase represents an ideal target for the development of new antibiotics which will be important in maintaining the health of the Australian community and also in protecting the community from the very real threat of bioterrorism organisms such as anthrax. This project is designed to identify molecules for development as new antibiotics that are effective against RNA polymerase.Read moreRead less
A Unique Target in the Purine Biosynthesis of the Pathogen Helicobacter pylori. The uptake systems of purine and analogues of the human pathogen Helicobacter pylori will be characterised because they can be utilised to introduce cytotoxic compounds into the cells. The first step in de novo purine biosynthesis of the bacterium is catalysed by two different enzymes, which are components of other biosynthetic pathways. These unique properties make them excellent potential therapeutic targets. Their ....A Unique Target in the Purine Biosynthesis of the Pathogen Helicobacter pylori. The uptake systems of purine and analogues of the human pathogen Helicobacter pylori will be characterised because they can be utilised to introduce cytotoxic compounds into the cells. The first step in de novo purine biosynthesis of the bacterium is catalysed by two different enzymes, which are components of other biosynthetic pathways. These unique properties make them excellent potential therapeutic targets. Their individual combined activities in purine biosynthesis will be characterised in situ and in vitro. Isogenic mutants with inactivated genes encoding for these enzymes will be constructed to investigate their role in the survival of the organism.Read moreRead less