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1 VICARTE, Departamento de Conservação e Restauro, Faculdade de Ciências e Tecnologia, Universidade Nova de Lisboa, Monte da Caparica, 2829-516 Caparica, Portugal
2 Departamento de Conservação e Restauro, Faculdade de Ciências e Tecnologia, Universidade Nova de Lisboa, Monte da Caparica, 2829-516 Caparica, Portugal
3 Centro de Petrologia e Geoquímica, Departamento de Engenharia de Minas e Georrecursos, Instituto Superior Técnico, Av. Rovisco Pais, 1049-001 Lisboa, Portugal
4 Instituto de Recursos Naturales y Agrobiologia, CSIC, Apartado 1052, 41080 Sevilla, Spain
Correspondence
Maria Filomena Macedo
mfmd{at}fct.unl.pt
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ABSTRACT |
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 TOP ABSTRACT IntroductionCyanobacteria on monumentsGreen algae on monumentsSurvival strategies of...Biodeterioration of stoneConclusionREFERENCES |
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Introduction |
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TOPABSTRACTIntroductionCyanobacteria on monumentsGreen algae on monumentsSurvival strategies of...Biodeterioration of stoneConclusionREFERENCES |
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; Tiano et al., 1995; Cecchi et al., 2000; Lamenti et al., 2000; Tomaselli et al., 2000b; Crispim & Gaylarde, 2005). Due to their photoautotrophic nature, these micro-organisms develop easily on stone surfaces, giving rise to coloured patinas and incrustations (Fig. 1) (Tomaselli et al., 2000b). Identifying the micro-organisms involved in biodeterioration is one of the most important steps in the study of the microbial ecology of monumental stones. It can help us to understand the microbial biodiversity, the phases of colonization and the relationship among populations on the surfaces and between micro-organisms and substrata.
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The photosynthetic micro-organisms inventoried in this review were almost entirely found on outdoor monuments located in the Mediterranean Basin area. The prevailing Mediterranean climate in this region is characterized by mild and rainy winters, warm and dry summers and, usually, extended periods of sunshine throughout most of the year; temperatures during winter rarely reach freezing (except in areas with a high elevation), and snow is unusual.
This review catalogues the cyanobacteria and green algae occurring on stone monuments from the Mediterranean area, together with the type of mineral substratum, occurrence locations and references. The data gathered together here will be useful for the study of biological colonization in cultural heritage buildings, and should provide a basis for laboratory experiments on stone colonization, allowing for the selection of single species or mixed communities of micro-organisms and/or stone substrata for ecological studies.
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Cyanobacteria on monuments |
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TOPABSTRACTIntroductionCyanobacteria on monumentsGreen algae on monumentsSurvival strategies of...Biodeterioration of stoneConclusionREFERENCES |
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lists the monuments, statues and historic buildings reported in the literature covered in this review. Most of these works of art were built in limestone (32 %) and marble (30 %). Travertine (7 %) and dolomite (2 %) were less represented lithotypes (Fig. 2).
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lists the cyanobacteria detected on monuments and works of art in the Mediterranean Basin, together with the substratum. The data on cyanobacteria occurring on stone monuments and works of art is rather wide. A total of 96 taxa of cyanobacteria were found. The genus Gloeocapsa (Fig. 3) was the most widespread, occurring on 20 of the 45 monuments reported, on all substrata and represented by eight species. Cyanobacterial species from the genera Phormidium and Chroococcus were able to colonize five of the six stone substrata considered and they were represented by high species diversity: eight species of Phormidium and four species of Chroococcus were reported. Chroococcus species were detected colonizing 13 different monuments while Phormidium was found on 15 monuments. Pleurocapsa occurred on 13 monuments but only one species was identified, while the genus Scytonema occurred with five species and colonizing eight different monuments. Therefore, we can consider that Gloeocapsa, Phormidium and Chroococcus are the most common cyanobacterial genera on the monuments of the Mediterranean Basin. This is in accordance with Ortega-Calvo et al. (1995), who stated that the most common species found on monuments located in Europe, America and Asia belong to the genera Gloeocapsa, Phormidium, Chroococcus and Microcoleus. These genera are ubiquitous and therefore their presence is not strictly related to a specific lithic substratum or climate. Tomaselli et al. (2000b) also found that the data reported in the literature did not establish a clear relationship between organisms and the nature of the substratum. Nevertheless, these authors contend that Phormidium tenue, Phormidium autumnale and Microcoleus vaginatus prefer siliceous substrata.
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shows the number of cyanobacterial taxa present on each lithotype. According to the literature reviewed in this study, marble and limestone were colonized by about the same number of taxa (56 and 55, respectively). Travertine was a lithotype present only in 7 % of the monuments reported but it was colonized by a considerable number of taxa (23). Granite was colonized by a very low number of different taxa (only 10) when compared with limestone or marble. According to Ortega-Calvo et al. (1995), granite, with a very low porosity and pH, is an unfavourable substratum for cyanobacteria. In fact, the colonization of stones is closely correlated with porosity, roughness, hygroscopicity and capillary water absorption, which strongly influence water availability for micro-organisms (Urzì & Realini, 1998; Prieto & Silva, 2005; Miller et al., 2006).
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observed that samples taken near ground level were characterized by the absence of cyanobacteria, which were however present in samples taken from places more exposed to sunlight. Detailed observations in different monuments subjected to lower humidity suggested that the formation of a photosynthetic biofilm developing on the stone surface is related substantially to the length of the period of wetness and the spatial orientation of the substratum (Fig. 5). In addition, the physico-chemical characteristics of the materials favour the establishment of photosynthetic communities at depths that also depend on external environmental factors, especially light, which influences the total biomass of the community (Saiz-Jimenez, 1995). Bellinzoni et al. (2003) assessed the correlation between biological growth and environmental factors on travertine. The biological colonization showed a characteristic trend with the microclimate (orientation and presence or absence of trees).
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). The endolithic microhabitat gives protection from intense solar radiation and desiccation, and it provides mineral nutrients, rock moisture and growth surfaces (Friedmann, 1982; Bell, 1993; Walker et al., 2005). However, very few studies report the presence of endolithic cyanobacteria in the monuments of the Mediterranean Basin. Pentecost (1992) observed that endolithic growth was often obscured by superficial algal growths, and consequently overlooked. In our study, we noted endolithic growth of Phormidium, Plectonema, Chroococcopsis, Synechocystis and Synechococcus on Ordem de São Francisco Church, Portugal. These cyanobacteria were found growing under a black patina in granite (Pereira de Oliveira, 2008; Pereira de Oliveira et al., 2008). Phormidium was also found growing under a black sulphated crust developed on limestone in the Cathedral of Seville, Spain (Saiz-Jimenez et al., 1991). Endolithic growth of Hyella fontana was also observed in marble statues in Rome, Italy (Giaccone et al., 1976).
Cyanobacteria can live in rock fissures and cracks and in cavities occurring in porous transparent rocks such as sandstones and marble, but not in dense dark volcanic rocks. Chasmo- and endolithic cyanobacteria and chlorophyta were present in all samples examined from the marbles of the Parthenon and Propylaea Acropolis in Athens, Greece (Anagnostidis et al., 1991). Cryptoendolithic cyanobacteria such as Chroococcidiopsis live beneath rock surfaces together with cryptoendolithic lichens, fungi and bacteria. Chroococcidiopsis can survive extreme cold, heat and arid conditions and it may be the single autotrophic organism most tolerant to environmental extremes (Graham & Wilcox, 2000).
The cyanobacterium Borzia periklei, a rare aerophytic species – first described and found on the marbles of the Parthenon, Greece (Anagnostidis & Komarek, 1988) – is of particular interest. The second record was in the stuccos of the Roman town of Baelo Claudia, South Spain (Hernandez-Marine et al., 1997) (Fig. 6). The growth of this cyanobacterium on mortars suggests a good adaptation to carbonate environments. Mortars, not considered in this review, can provide niches which are suitable for relatively rare species or species peculiar to other, very specific, ecological niches. The high porosity and the mobilization of salts, together with the humidity retained in the inner layers of the wall, facilitate the colonization and growth of such organisms.
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). The sheath can also play an important role in adhesion to the substratum (Fig. 7). Sometimes sheaths may be pigmented. This is particularly evident in some cyanobacterial genera such as Gloeocapsa or Scytonema that have thick sheaths with intense colours, being the expression of different ecological stages and environmental adaptations. Cyanobacteria can take on a yellow-brown colour under low-nitrogen conditions due to a reduction in chlorophyll and phycocyanin and an increase in carotenoids. In other cases, it has been shown that pigmentation changes in response to environmental factors including light intensity, light quality, nutrient availability, temperature and the age of cells. Bartolini et al. (2004), in a study on monuments located on the Appia Antica road (Rome), observed that grey-black patinas were widespread on marble and travertine stoneworks exposed to sun irradiation, and that green patinas were more frequent on tufaceous materials and mortar in shaded areas. These coloured patinas cause aesthetic damage, giving an unsightly appearance of neglect to buildings, statues and monuments.
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Green algae on monuments |
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TOPABSTRACTIntroductionCyanobacteria on monumentsGreen algae on monumentsSurvival strategies of...Biodeterioration of stoneConclusionREFERENCES |
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). In Table 3, 76 taxa of chlorophyta found on monuments and works of art in the Mediterranean Basin are listed, together with the substratum on which they occurred. Most of these genera are soil algae. This is predictable, since the main source of biological colonization of stone is the surrounding soil, containing large numbers of many different types of bacteria, algae and fungi, which can contaminate the stone shortly after quarrying. Windblown detritus or rising groundwater infiltration may also be a source of stone inoculation (Koestler, 2000).
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we can see that chlorophyta were not found on dolomite. The genus Chlorella was the most widespread, occurring on 20 of the monuments reported, represented by four species and occurring on four different substrata. Stichococcus was found on 17 monuments and was also present on four substrata. Members of the chlorophyte genus Chlorococcum were detected on all the stone substrata considered, with the exception of dolomite, and this genus occurred on 15 distinct monuments. Therefore, we can consider that Chlorella, Stichococcus and Chlorococcum are the green algal genera most abundant on the monuments of the Mediterranean Basin. This is in fair agreement with Ortega-Calvo et al. (1995), who stated that Chlorella, Chlorococcum Klebsormidium and Trentepohlia can be readily observed in monuments located in Europe, America and Asia. However, it was not possible to establish a correlation between these genera and a specific substratum or climate.
Klebsormidium, Trebouxia and Trentepohlia (Fig. 1) also showed a significant representation among the chlorophyte genera colonizing stone substrata in the Mediterranean Basin. The occurrence of Trebouxia and Trentepohlia indicates that these microalgae could be involved in the lichenization process leading to colonization by lichens. In fact, the genus Trebouxia occurs in approximately 20 % of all lichens and has rarely been found free-living. Regarding endolithic growth of green algae, Trentepohlia, Chorella and Klebsormidium were found growing under a black patina, probably a cryptoendolithic niche, in the Ordem de São Francisco Church, Portugal (Pereira de Oliveira, 2008; Pereira de Oliveira et al., 2008). Cryptoendolithic growth of Stichococcus bacillaris was also observed in granite from the Cathedral of Toledo, Spain (Ortega-Calvo et al., 1995).
Fig. 8 shows the number of chlorophyta taxa present in each lithotype. Limestone was colonized by the highest number of taxa (34), followed by marble (27). Travertine and granite were colonized by about the same number of taxa (21 and 22, respectively), although the number of monuments built of travertine (7 %) was considerably lower than the number made of granite (18 %). From Table 3 we can see that Oocystis, Cosmarium and Staurastrum species appear almost exclusively on travertine. Nevertheless, the majority of the results suggest that green algae can colonize a wide variety of substrata and this is primarily related to the physical characteristics of the stone surface (porosity, roughness and permeability) and secondarily to the nature of the substratum. This is in accordance with Tiano et al. (1995). These authors carried out a laboratory experiment using two photosynthetic strains: a green alga (Pleurococcus) and a cyanobacterium (Lyngbya), inoculated on 12 different lithotypes exposed to constant climatic conditions. They demonstrated that the preferential colonization (percentage of stone surface coverage) was correlated mainly with physical characteristics of the stone (roughness and porosity) while the chemical composition had low influence (Tiano et al., 1995).
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Survival strategies of cyanobacteria and algae on stone |
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TOPABSTRACTIntroductionCyanobacteria on monumentsGreen algae on monumentsSurvival strategies of...Biodeterioration of stoneConclusionREFERENCES |
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). This leads to species characteristic of very different habitats and ecological requirements. Moreover, it was observed that the most representative genera occurring in unfavourable environments develop different strategies to survive in such conditions; these include the production of a sheath composed of extracellular polymeric substances (EPS) outside the cyanobacterial cells (Fig. 7) as a protection against desiccation (Urzì & Realini, 1998; Tomaselli, 2003). Due to the presence of these colloidal polymeric substances, the biofilm incorporates large amounts of water into its structure, ensuring the maintenance of moisture by balancing changes in humidity and temperature, which permits cyanobacteria and algae to resist drought periods (Gómez-Alarcón et al., 1995; Saiz-Jimenez, 1999; Schumann et al., 2005). These biofilms are composed of populations or communities of different micro-organisms (microalgae, cyanobacteria, bacteria and fungi) immobilized on the stone surface (substratum) and frequently embedded in an organic polymer matrix formed by EPS, such as polysaccharides, lipopolysaccharides, proteins, glycoproteins, lipids, glycolipids, fatty acids and enzymes (Young et al., 2008). EPS are also responsible for binding cells and other particulate matter together (cohesion) and to the substratum (adhesion) (Cecchi et al., 2000; Warscheid & Braams, 2000) (Fig. 9).
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; Donlan, 2002). Tomaselli et al. (2000a) showed that high stone porosity and rough surface, together with environmental factors, played a greater role than mineral composition in promoting microbial establishment. The most important of the environmental factors is water availability. Adequate temperature and solar irradiance, and type of atmospheric deposition, are also relevant factors (Tomaselli et al., 2000a).
Endolithic colonization is also a successful survival strategy when surface environmental conditions are adverse for life on stone. The protection provided by the rock leads to the abundance of endolithic micro-organisms in extreme environments, such as cold and hot deserts, semiarid lands and even polar regions (Friedmann, 1982; Bell, 1993; Walker et al., 2005).
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Biodeterioration of stone |
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TOPABSTRACTIntroductionCyanobacteria on monumentsGreen algae on monumentsSurvival strategies of...Biodeterioration of stoneConclusionREFERENCES |
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). These micro-organisms have an important role in the disfigurement of monuments and stone works of art (Figs 1 and 5). Moreover, there are several references in the literature that point to direct decay mechanisms caused by these photosynthetic micro-organisms (Anagnostidis et al., 1991; Griffin et al., 1991; Krumbein & Urzì, 1991; Ortega-Calvo et al., 1992, 1993b; Wakefield & Jones, 1998; Saiz-Jimenez, 1999; Warscheid & Braams, 2000; Crispim & Gaylarde, 2005; Zurita et al., 2005). In fact, cyanobacteria and green algae living in rocks can enhance soil formation and water retention. It has been estimated that 20–30 % of stone deterioration is a result of biological activity (Wakefield & Jones, 1998). Two types of biodeterioration can be considered: biogeophysical and biogeochemical. While the effects and extent of biogeochemical deterioration processes are controlled and determined by the chemistry of minerals and the binding cement of each rock, biogeophysical mechanisms are mostly regulated by the porosity and shape of the interior surface of the rocks (Warscheid & Braams, 2000).
Biogeophysical deterioration can be defined as the mechanical damage caused by exerted pressure during biological growth, resulting in surface detachment, superficial losses, or penetration and increased porosity (Griffin et al., 1991). This kind of deterioration also occurs due to the presence of cyanobacterial and algal biofilms that undergo large volume changes and exert considerable force through cycles of drying and moistening, loosening rock grains (Saiz-Jimenez, 1999). This can lead to the alteration of the stone's pore-size distribution and result in changes of moisture circulation patterns and temperature response (Saiz-Jimenez, 1999; Warscheid & Braams, 2000). Furthermore, the formation of crusts induced by cyanobacterial and algal growth also results in longer moisture retention at the stone surface, increasing the stone colonization potential.
Biogeochemical deterioration is the direct action caused by the metabolic processes of organisms on the substratum. The biogenic release of corrosive acids is probably the best known and most commonly investigated biogeochemical damage mechanism in inorganic materials. The process, known as biocorrosion, involves the release of organic acids which can etch or solubilize stone, the exudation of organic chelating agents which sequester metallic cations from stone, or the conversion of inorganic substances by redox reactions which form acids that etch stone and contribute to salt formation (Griffin et al., 1991; Fernandes, 2006). For instance, aerobic micro-organisms produce respiratory carbon dioxide which becomes carbonic acid and contributes to dissolution of stone and soluble salt formation (Griffin et al., 1991; Wakefield & Jones, 1998). The precipitation of calcium salts on cyanobacterial cells growing on limestone suggests the migration of calcium from neighbouring sites (Fig. 10) (Ariño et al., 1997; Crispim & Gaylarde, 2005). In addition, the production of organic acids such as lactic, oxalic, succinic, acetic, glycolic and pyruvic has been found and associated with the dissolution of calcite in calcareous stones (Danin & Caneva, 1990; Caneva et al., 1992). Endolithic photosynthetic micro-organisms actively dissolve carbonates to enable penetration into the stone, enhancing stone porosity (Griffin et al., 1991; Fernandes, 2006). Furthermore, the slimy surfaces of microbial biofilms favour the adherence of airborne particles (dust, pollen, spores, carbonaceous particles from combustion of oil and coal), giving rise to hard crusts and patinas (Saiz-Jimenez, 1999).
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), low-temperature SEM (LTSEM) and environmental SEM (ESEM) (Roldán et al., 2004; Ascaso et al., 2004; De los Ríos et al., 2004; Wierzchos et al., 2004; De los Ríos & Ascaso, 2005). CSLM studies revealed that cells in biofilms are organized within a complex exopolymeric matrix, and the biofilm consists of a heterogeneous distribution of cells and cellular aggregates with void spaces or water channels (Costerton et al., 1995; Kawaguchi & Decho, 2002). The use of microscopy techniques to study microbial colonies in their natural microhabitat has also demonstrated that EPS penetrate small pore spaces of the substratum and may facilitate subsequent penetration of the micro-organisms into the material, increasing stone biodeterioration. These studies have shown that penetration of growing organisms into rock and the diffusion of their excreted products may occur to depths of several millimetres (Saiz-Jimenez, 1999; Koestler, 2000; Salvadori, 2000; Pohl & Schneider, 2002; Young et al., 2008). Pohl & Schneider (2002) applied computerized image analysis to detect and quantify the biomass and depth of penetration of endolithic micro-organisms into carbonate rock surfaces. The natural carbonate rocks investigated were endolithically colonized by lichens, cyanobacteria, algae and fungi. Photosynthetic micro-organisms from intensely insolated dry sites retreated to depths of 150-250 µm below the rock surface and showed ‘cushions’ of EPS oriented toward the surface, which protect them against intense light and provide water retention. In addition, the authors demonstrated that as soon as the endolithic biofilm was established it exerted an overall protective effect on the carbonate rocks. Salvadori (2000) examined by SEM the endolithic communities inhabiting Italian stone monuments and observed that euendolithic cyanobacteria and fungi could easily penetrate the calcite crystals of marble. The periodic contraction and expansion of EPS induces mechanical stress on the stone surface, particularly when the polymer penetrates into the pores, stimulating defoliation of the biofilm and the underlying substratum, evident at macroscopic scale (Saiz-Jimenez, 1999; Young et al., 2008; Kemmling et al., 2004). Krumbein & Urzì (1991) reported the physical action on and within marble through biofilms and microbial growth, demonstrating that stability and activity of water in polyionic gel matrix was crucial for the physical reactions and interactions between microbiota and rock and rock porosity, giving rise to decomposition and detachment of grains, chips or scales in marbles. Apart from direct deterioration of stone substrata, microbial biofilms, especially those formed by photosynthetic micro-organisms, play an indirect role in stone biodeterioration as described by Ortega-Calvo et al. (1992). It was concluded that photosynthetic micro-organisms contribute directly to stone deterioration through physical and chemical action and indirectly through the synergistic interactions with heterotrophic micro-organisms such as fungi and bacteria. The accumulation of photosynthetic biomass on stone surfaces provides nutrients for the growth of other communities which graze on cyanobacterial and algal polysaccharides and cell debris, contributing to accelerating the deterioration of the stone (Tiano, 1998; Crispim & Gaylarde, 2005; McNamara & Mitchell, 2005; Fernandes, 2006). Therefore, the role of cyanobacteria and green algae in the degradation of cultural heritage cannot be neglected. The detection and identification of these micro-organisms is extremely important for future studies of the biodeteriogenic process and the development of prevention and control methods.
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Conclusion |
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TOPABSTRACTIntroductionCyanobacteria on monumentsGreen algae on monumentsSurvival strategies of...Biodeterioration of stoneConclusionREFERENCES |
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Cyanobacteria and green algae play an important role in the deterioration of monuments and other stone works of art, being responsible for aesthetic, biogeophysical and biogeochemical damage. Future work should focus on ecological and physiological studies of specific species of these micro-organisms in order to gain a better understanding of their role in stone colonization and biodeterioration processes. Moreover, an interdisciplinary team working on the same ‘case study’ is necessary in order to simultaneously investigate all the factors involved in the biodeterioration process such as mineralogical-petrographic, physico-chemical and climatic (and microclimatic) parameters.
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ACKNOWLEDGEMENTS |
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TOPABSTRACTIntroductionCyanobacteria on monumentsGreen algae on monumentsSurvival strategies of...Biodeterioration of stoneConclusionREFERENCES |
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