Lab

Chris Greening's Lab


Featured research (4)

Molecular hydrogen (H2) is available in trace amounts in most ecosystems through atmospheric, biological, geochemical, and anthropogenic sources. Aerobic bacteria use this energy-dense gas, including at atmospheric concentrations, to support respiration and carbon fixation. While it was thought that aerobic H2 consumers are rare community members, here we summarize evidence suggesting that they are dominant throughout soils and other aerated ecosystems. Bacterial cultures from at least eight major phyla can consume atmospheric H2. At the ecosystem scale, H2 consumers are abundant, diverse, and active across diverse soils and are key primary producers in extreme environments such as hyper-arid deserts. On this basis, we propose that H2 is a universally available energy source for the survival of aerobic bacteria.
Acinetobacter baumannii is a high-risk pathogen due to the rapid global spread of multi-drug resistant lineages. Its phylogenetic divergence from other ESKAPE pathogens means that determinants of its antimicrobial resistance can be difficult to extrapolate from other widely studied bacteria. A recent study showed that A. baumannii upregulates production of an outer-membrane lipoprotein, which we designate BonA, in response to challenge with polymyxins. Here we show that BonA has limited sequence similarity and distinct structural features compared to lipoproteins from other bacterial species. Analyses through X-ray crystallography, small-angle X-ray scattering, electron microscopy, and multiangle light scattering demonstrate that BonA has a dual BON-domain architecture and forms a decamer via an unusual oligomerization mechanism. This analysis also indicates this decamer is transient, suggesting dynamic oligomerization plays a role in BonA function. Antisera recognizing BonA shows it is an outer membrane protein localized to the divisome. Loss of BonA modulates the density of the outer membrane, consistent with a change in its structure or link to the peptidoglycan, and prevents motility in a clinical strain (ATCC 17978). Consistent with these findings, the dimensions of the BonA decamer are sufficient to permeate the peptidoglycan layer, with the potential to form a membrane-spanning complex during cell division.
It is commonly thought that bacterial distributions show lower spatial variation than for multicellular organisms. In this article, we present evidence that these inferences are artifacts caused by methodological limitations. Through leveraging innovations in sampling design, sequence processing, and diversity analysis, we provide multifaceted evidence that bacterial communities in fact exhibit strong distribution patterns. This is driven by selection due to factors such as local soil characteristics. Altogether, these findings suggest that the processes underpinning diversity patterns are more unified across all domains of life than previously thought, which has broad implications for the understanding and management of soil biodiversity.
Mycobacteria are major environmental microorganisms and cause many significant diseases, including tuberculosis. Mycobacteria make an unusual vitamin-like compound, F 420 , and use it to both persist during stress and resist antibiotic treatment. Understanding how mycobacteria make F 420 is important, as this process can be targeted to create new drugs to combat infections like tuberculosis. In this study, we show that mycobacteria make F 420 in a way that is different from other bacteria. We studied the molecular machinery that mycobacteria use to make F 420 , determining the chemical mechanism for this process and identifying a novel chemical intermediate. These findings also have clinical relevance, given that two new prodrugs for tuberculosis treatment are activated by F 420 .

Lab head

Chris Greening
Department
  • Department of Microbiology
About Chris Greening
  • Research in my group focuses on how environmentally and medically important bacteria survive in different ecosystems. A key finding of my research is that bacteria are more metabolically flexible than previously thought. For example, we have shown that soil bacteria scavenge trace gases from the atmosphere (e.g. hydrogen) when their preferred organic substrates (e.g. sugars) are unavailable. Likewise, we demonstrated that medically-important mycobacteria survive during hypoxia by switching from aerobic respiration to fermentation. We take an integrative approach to understand biological processes at all levels of organisation: from enzymatic mechanism to ecosystem importance. This research has broader implications for understanding global change, infectious disease, and biodiversity.

Members (11)

Pok Man Leung
  • Monash University (Australia)
Eleonora Chiri
  • Monash University (Australia)
Thanavit Jirapanjawat
  • Monash University (Australia)
Rachael Lappan
  • Monash University (Australia)
Ya-Jou Chen
  • McGill University
Ashleigh Kropp
  • Monash University (Australia)
Zahra Fatima Islam
  • University of Melbourne
David L Gillett
  • Monash University (Australia)