Geometrical Distribution of Cryptococcus neoformans Mediates Flower-Like Biofilm Development.

William Lopes,Augusto Schrank,Susana Frases,Rita M C De Almeida,Lívia Kmetzsch,Glauber R De Sousa Araujo,Mendeli H Vainstein,Marilene H Vainstein,Charley C Staats

doi:10.3389/fmicb.2017.02534

Abstract

Microbial biofilms are highly structured and dynamic communities in which phenotypic diversification allows microorganisms to adapt to different environments under distinct conditions. The environmentally ubiquitous pathogen Cryptococcus neoformans colonizes many niches of the human body and implanted medical devices in the form of biofilms, an important virulence factor. A new approach was used to characterize the underlying geometrical distribution of C. neoformans cells during the adhesion stage of biofilm formation. Geometrical aspects of adhered cells were calculated from the Delaunay triangulation and Voronoi diagram obtained from scanning electron microscopy images (SEM). A correlation between increased biofilm formation and higher ordering of the underlying cell distribution was found. Mature biofilm aggregates were analyzed by applying an adapted protocol developed for ultrastructure visualization of cryptococcal cells by SEM. Flower-like clusters consisting of cells embedded in a dense layer of extracellular matrix were observed as well as distinct levels of spatial organization: adhered cells, clusters of cells and community of clusters. The results add insights into yeast motility during the dispersion stage of biofilm formation. This study highlights the importance of cellular organization for biofilm growth and presents a novel application of the geometrical method of analysis.

Highlights

Microorganisms have been traditionally analyzed using planktonic microbial cells; this lifestyle is not necessarily related with the growth of microbes in their most prevalent habitat
Microbial biofilms are recognized as highly structured and dynamic communities, in which phenotypic diversification allows microorganisms to adapt to diverse environments under different conditions (Watnick and Kolter, 2000; Parsek and Fuqua, 2004; Drescher et al, 2016; Gulati and Nobile, 2016; Sheppard and Howell, 2016)
The degree of order was numerically quantified and we revealed a correlation between higher levels of biofilm formation and more ordered underlying structures

Summary

Introduction

Microorganisms have been traditionally analyzed using planktonic microbial cells; this lifestyle is not necessarily related with the growth of microbes in their most prevalent habitat. A wide range of microorganisms are able to switch from a planktonic to a colonial lifestyle in the form of a biofilm, creating aggregated communities that are enclosed by an extracellular matrix (ECM) (Costerton et al, 1995). Microbial biofilms are recognized as highly structured and dynamic communities, in which phenotypic diversification allows microorganisms to adapt to diverse environments under different conditions (Watnick and Kolter, 2000; Parsek and Fuqua, 2004; Drescher et al, 2016; Gulati and Nobile, 2016; Sheppard and Howell, 2016). Waste products might be removed through this system (Flemming and Wingender, 2010)

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Conclusion