Etudes physiologiques et moléculaires de l'adaptation des Mucor aux matrices fromagères

In the cheese industry context, Mucor species exhibit an ambivalent behavior, as some species are essential technological organisms contributing to the required organoleptic characteristics of some cheeses while some others can be spoiling agents. The present study aimed at better understanding this ambivalence and investigating the putative adaptation mechanisms to cheese existing in Mucor technological species. Morphology and radial growth of 7 representative Mucor species: technological, contaminant and non-cheese related (plant endophyte) species were monitored on different media (synthetic, cheese-mimicking media and cheese) in function of key parameters for cheese manufacture (temperature, aw, pH). Cardinal values were determined on synthetic medium and as a result a predictive model was proposed and validated on cheese matrices for the temperature parameter. Interestingly, cheese technological species exhibited higher optimal growth rates on cheese related matrices than on synthetic media, while the opposite was observed for non-technological species. A comparative proteomic approach allowed unraveling the main metabolic pathways playing a role in growth of 4 of the 7 studied strains on both synthetic medium and cheese-mimicking medium. This proteomic study also highlighted the occurrence of 35 proteins specifically expressed by the technological strains M. lanceolatus UBOCC-A-109153 on the cheese-mimicking medium. Putative competitive and adaptative advantages of these hypothetical adaptation markers will be tested through additional investigations.Dans le contexte fromager, les champignons filamenteux du genre Mucor ont un rôle ambivalent. En fonction du fromage considéré, ils peuvent être assimilés à des microorganismes d’altération responsables de défauts de fabrication ou au contraire contribuer au développement des qualités organoleptiques des produits. Dans le cadre de ce travail, nous avons souhaité confirmer et objectiver la dichotomie classiquement faite en industrie fromagère entre espèces technologiques et espèces contaminantes, et investiguer les mécanismes d’adaptation potentiels mis en oeuvre chez les espèces technologiques. La morphologie et la croissance radiale de 7 souches représentatives d’espèces technologiques, contaminantes et non-fromagères (endophyte) de Mucor ont été étudiées sur différents milieux (synthétique, mimant le fromage et fromager) en fonction de facteurs clés du processus de production des fromages (température, aw, pH). Les valeurs cardinales de croissance ont été déterminées sur milieu synthétique, un modèle prédictif a été proposé et validé sur matrices fromagères pour le facteur température et la meilleure faculté de croissance des souches technologiques sur milieux fromagers par rapport au milieu synthétique a été démontrée. Une approche de protéomique comparée a permis de décrire les voies métaboliques mises en jeu par 4 de ces souches dans les deux types d’environnement, fromager et non-fromager, et 35 protéines spécifiquement surexprimées par la souche technologique M. lanceolatus UBOCC-A-109153 sur milieu mimant le fromage ont été identifiées. Les avantages compétitifs associés à ces potentiels marqueurs d’adaptation vont faire l’objet d’investigations complémentaires

Mucor: A Janus-faced fungal genus with human health impact and industrial applications

International audienceThe Mucor genus, a polyphyletic group pertaining to early diverging lineages of fungi, includes a high number of ubiquitous species. Some species have positive or negative impacts on human activities. Indeed, certain pathogenic Mucor species are a threat for animal and human health and identified more frequently as mycosis causative agents, especially in immunocompromised patients. On the contrary, a small number of Mucor species have been used for centuries in food manufacturing for cheese ripening or Asian fermented food production. Some species are also used as biotechnologically important microorganisms due to their high growth rates, dimorphism (for certain species) and their previously unsuspected potential for secondary metabolite production. Despite all these important roles played by Mucor spp., they have been less investigated than ascomycetous or basidiomycetous species and their taxonomy, metabolism and ecology are less documented when compared to their counterparts in the so-called higher fungi. Nevertheless, research focusing most often on the emblematic Mucor circinelloides species has led to increased knowledge on the biology of this genus, and overall on fungal biology. This is particularly documented for fungal dimorphism or light-induced gene regulation. The aim of this review is to give an overview of the current knowledge on Mucor morphology, taxonomy, ecology and genetics and of its importance regarding human health and industrial applications

Dataset of differentially accumulated proteins in Mucor strains representative of four species grown on synthetic potato dextrose agar medium and a cheese mimicking medium

International audienceThe data presented are associated with the “Proteomic analysis of the adaptative response of Mucor spp. to cheese environment” (Morin-Sardin et al., 2016) article [1]. Mucor metabolism is poorly documented in the literature and while morphology and growth behavior suggest potential adaptation to cheese for some strains, no adaptation markers to cheese environment have been identified for this genus. To establish the possible existence of metabolic functions related to cheese adaptation, we used a gel based 2-DE proteomic approach coupled to LC–MS/MS to analyze three strains from species known or proposed to have a positive or negative role in cheese production as well as a strain from a non-related cheese-species

Proteomic analysis of the adaptative response of Mucor spp. to cheese environment

International audienceIn the cheese industry context, Mucor species exhibit an ambivalent behavior as some species are essential “technological” organisms of some cheeses while others can be spoiling agents. Previously, we observed that cheese “technological” species exhibited higher optimal growth rates on cheese related matrices than on synthetic media. This growth pattern combined with morphological differences raise the question of their adaptation to cheese. In this study, using a comparative proteomic approach, we described the metabolic pathways of three Mucor strains considered as “technological” or “contaminant” in the cheese environment (M. lanceolatus UBOCC-A-109153, M. racemosus UBOCC-A-109155, M. circinelloides CBS 277-49) as well as a non-cheese related strain (M. endophyticus CBS 385-95). Overall, 15.8 to 19.0% of the proteomes showed a fold change ≥ 1.6 in Potato Dextrose Agar (PDA) versus Cheese Agar (CA), a cheese mimicking-medium. The 289 differentially expressed proteins identified by LC MS-MS analysis were mostly assigned to energy and amino-acid metabolisms in PDA whereas a higher diversity of biological processes was observed for cheese related strains in CA. Surprisingly, the vast majority (72.9%) of the over-accumulated proteins were different according to the considered medium and strain. These results strongly suggest that the observed better adaptative response of “technological” strains to cheese environment is mediated by species-specific proteins.ăBiological significanceăThe Mucor genus consists of a multitude of poorly known species. In the food context, few species are known for their positive role in the production of various food products, including cheese, while others are spoiling agents. The present study focused on the analysis of morphological and proteome differences of various Mucor spp. representative strains known as either positively (hereafter referred as “technological”) or negatively (hereafter referred as “contaminant”) associated with cheese or non-related to cheese (endophyte) on two different media, a synthetic medium and a cheese-mimicking medium. The main goal was to assess if adaptative traits of “technological” strains to the cheese environment could be identified. This work was based on observations we did in a recently published physiological study (Morin-Sardin et al., 2016). One of the important innovative aspects lies in the use for the first time of an extensive 2-DE approach to compare proteome variations for 4 strains on two different media. Results obtained offered an insight in the metabolic mechanisms associated with growth on a given medium and showed that adaptation to cheese environment is probably supported by species-specific proteins. The obtained data represent an essential step point for more targeted studies at the genomic and transcriptomic levels