Hydrobiologia (2013) 719:43–58 DOI 10.1007/s10750-012-1302-y MEDITERRANEAN CLIMATE STREAMS Review Paper Microbial biofilm structure and organic matter use in mediterranean streams Anna M. Romanı́ • Stefano Amalfitano • Joan Artigas • Stefano Fazi • Sergi Sabater • Xisca Timoner • Irene Ylla • Annamaria Zoppini Received: 26 January 2012 / Accepted: 31 August 2012 / Published online: 12 October 2012 Ó Springer Science+Business Media B.V. 2012 Abstract River and stream biofilms in mediterranean fluvial ecosystems face both extreme seasonality as well as arrhythmic fluctuations. The hydrological extremes (droughts and floods) impose direct changes in water availability but also in the quantity and quality of organic matter and nutrients that sustain the microbial growth. This review analyzes how these ecological pulses might determine unique properties of biofilms developing in mediterranean streams. The paper brings together data from heterotrophic and autotrophic community structure, and extracellular enzyme activities in biofilms in mediterranean Guest editors: N. Bonada & V. H. Resh / Streams in Mediterranean climate regions: lessons learned from the last decade A. M. Romanı́ (&) S. Sabater X. Timoner I. Ylla Institute of Aquatic Ecology, University of Girona, Campus de Montilivi, 17071 Girona, Spain e-mail: [email protected] S. Amalfitano S. Fazi A. Zoppini Water Research Institute (IRSA), National Research Council (CNR), Via Salaria km 29.3-CP10, 00015 Monterotondo, Italy J. Artigas Irstea, 3 Quai Chauveau CP 220, 69336 Lyon, France S. Sabater X. Timoner Catalan Institute for Water Research (ICRA), Emili Grahit 101, Edifici H2O Parc Cientı́fic i Tecnològic de la Universitat de Girona, 17003 Girona, Spain streams. Mediterranean stream biofilms show higher use of peptides during the favorable period for epilithic algae development (spring), and preferential use of cellulose and hemicellulose in autumn as a response to allochthonous input. The drying process causes the reduction in bacterial production and chlorophyll biomass, but the rapid recovery of both autotrophs and heterotrophs with rewetting indicates their adaptability to fluctuations. Bacteria surviving the drought are mainly associated with sediment and leaf litter which serve as ‘‘humid refuges’’. Some algae and cyanobacteria show resistant strategies to cope with the drought stress. The resistance to these fluctuations is strongly linked to the streambed characteristics (e.g., sediment grain size, organic matter accumulation, nutrient content). Keywords Biofilm Extracellular enzymes Drought resistance Bacteria Algae Mediterranean river Introduction River and stream biofilms are microbial assemblages of autotrophic and heterotrophic microorganisms that are attached to organic and inorganic surfaces (rocks, cobbles, sediment grains, leaf litter, wood). Bacteria, algae, fungi, and protozoa developing in a biofilm share a unique three-dimensional structure usually embedded in polymeric materials (polysaccharides 123 44 and peptides; Romanı́ et al., 2004a; Romanı́, 2010). As will be discussed in this article, biofilms play a key role in river biogeochemical cycles (organic and inorganic matter cycling). Microbial biofilms dwelling in streams and rivers face an ensemble of environmental factors that vary spatially and temporally (light regime, nutrient and dissolved organic matter (DOM) availability, water chemistry, and flow; Roberts et al., 2004; Stanley et al., 2004; Artigas et al., 2009). In mediterranean streams (med-streams), water flow has huge fluctuations from basal conditions to drought and floods. Frequency and severity of droughts strongly modulate river ecology (Acuña et al., 2005) and biogeochemistry (Vázquez et al., 2011). During the aquatic-habitat-shrinking period, water warms up, increases in nutrient and dissolved substances, and pH also may show larger shifts (Ylla et al., 2010; Vázquez et al., 2011). During flood events, large quantities of organic material and nutrients are transported downstream (Bernal et al., 2005; Vázquez et al., 2007; Tzoraky et al., 2007). At the scale of the microbial biofilm, such fluctuations become extremely arrhythmic and highly dependent on the specific streambed substrata characteristics. This has been both described for bacterial heterotrophs and autototrophs that make use of summer drought ‘‘humid refuges’’ and result in high heterogeneity of the biofilm structure and ecological functioning in and at the surface of the river bed. In general, biofilm structure and function is sensitive to changes in nutrient content, temperature, oxygen, flow velocity, and light, which determine not only the biofilm community composition, but also its thickness, the relative abundance of autotrophs/heterotrophs, and ultimately its function (Gao et al., 2005; Besemer et al., 2009a, b; Ylla et al., 2009; Dı́az Villanueva et al., 2011). Among temperate forested streams, the seasonal dynamics of allochthonous and autochthonous organic matter inputs followed by the consequent biofilm microbial use and decomposition is quite common (Jones & Smock, 1991; Sinsabaugh & Follstad Shah, 2010). However, in med-streams, the unpredictable drying and flooding episodes exert an additional and critical abiotic control on microbial metabolism. In temporary ecosystems, the processing and transformation rates of available DOM are higher in wet than in dry periods, and changes in river sediment microbial activity and biomass occur in response to drying and 123 Hydrobiologia (2013) 719:43–58 reinundation (Tzoraky et al., 2007; Amalfitano et al., 2008; McIntyre et al., 2009). When river flow becomes fragmented in pools, a decrease in the use of peptides but increase in polysaccharide decomposition by the microbial biofilm has been reported, indicating a decrease in available fresh C and N organic matter sources as drought progresses (Ylla et al., 2010). Summer periods, moreover, are characterized by drops in biodegradable dissolved organic C and N concentrations (Ylla et al., 2010). During the wet to drought transition, a decrease in bacterial C production as well as a decrease in benthic chlorophyll content have been shown (Amalfitano et al., 2008; Ylla et al., 2010). During this period, processing rates of deposited material are likely to differ from those in flowing water, and periodic hypoxia in pools causes microbial metabolism to fluctuate between aerobic and anaerobic pathways (Chan et al., 2005). Thus, the resistance and recovery of the microbial autotrophs and heterotrophs in biofilms are relevant for the maintenance of the river function. The objective of this review is to synthetize the knowledge of biofilm structure and functioning in medstreams. For this purpose, the microbial biofilm structure and organic matter use in med-stream biofilms are analyzed from the perspective of the main ecological pulses (see Fig. 1). First, autochthonous and allochthonous organic matter inputs are summarized. Second, the seasonality of extracellular enzyme activities and activity ratios is synthesized and analyzed with empirical data collected from a collection of published studies on med-streams. Third, the specific bacterial community changes in sediment and the drought resistance of autotrophs as well as their relevance as refuges for further colonization during rewetting are further discussed. Finally, a comparison of med- and non-medstream biofilms is made in order to highlight potential unique characteristics of such microbial communities. The revision is mainly focussed on stream biofilms of the Mediterranean Basin because little information is available from other mediterranean regions. Seasonal sources of autochthonous versus allochthonous organic matter DOM comprises most of the carbon in streams and rivers (Volk et al., 1997), which is continuously Hydrobiologia (2013) 719:43–58 45 Fig. 1 Outline of seasonal changes in energy inputs for biofilm functioning in a Mediterranean Basin stream. The extracellular enzymes shown in the diagram are those corresponding to the highest capabilities measured for each period. The relevance of the different microbial components (alga, bacteria, fungi) are also shown supplied both from terrestrial input (allochthonous material) as well as from in-stream processes (autochthonous material). Allochthonous DOM sources mainly come from terrestrial plant materials (leachates from surrounding soils, grasses, and inputs from riparian trees; Graça, 1993). This allochthonous material is more recalcitrant, more resistant to biological degradation (Joffre et al., 2001), and encompasses heterogeneous refractory organic substances of high molecular weight (McDonald et al., 2004) and of low quality (Kaplan & Newbold, 1995) than autochthonous material. Specifically, in med-streams, among typically deciduous riparian vegetation, sclerophyllous-type vegetation is present, having hard leaves with thick cuticles and strong lignification, which could determine a greater recalcitrance of the allochthonous material. As in temperate regions, allochthonous inputs are generally seasonally pulsed, where the bulk of litter fall occurs in a short pulse in autumn (Fisher & Likens, 1973), with additional material entering the streams by lateral movement over the remainder of the year (Benfield, 1997). Alternatively, in med-streams, there are more protracted periods of litter fall, with peaks occurring at different times of the year in the Northern and Southern Hemispheres. In the Northern Hemisphere, the presence of autumn–winter or summer deciduous trees can explain the autumn peak and the extended period of litter production (Sabater et al., 2001; Artigas et al., 2004). In severe drought, the summer litter fall is extended from mid-summer to midautumn, which has been related to hydric stress (Acuña et al., 2007). In the Southern Hemisphere, the prolonged litter fall results from evergreen phenology whereby new leaf growth is balanced by almost simultaneous leaf fall (Gasith & Resh, 1999). Autochthonous DOM sources are produced by the autotrophic organisms (algae, cyanobacteria, mosses, phytoplankton, macrophytes) as a result of photosynthetic processes (extracellular release), as well as from predatory grazing, cell death and senescence, and viral lysis. This DOM is of low molecular weight and is the most labile and bioavailable in the stream pool (Bott et al., 1984; Bertilsson & Jones, 2003). It consists of a large array of biomolecules, including lipids, carbohydrates, polysaccharides, amino acids, proteins, waxes, and resins (Piccolo, 2001). This organic C source may be available mostly during episodes of high primary production when exudates are produced, and within biofilms where exudates and products of cell lysis become concentrated. During springtime biofilm blooms, stream DOC concentrations increase as much as 37%, apparently as a result of extracellular release by algae (Kaplan & Bott, 1989). In medstreams there are two light, leafless periods that are favorable for primary production. The first one, and 123 46 usually the most relevant, is in spring when the leaves have not yet sprouted on the trees and there are clear mild days. The second one is in autumn, when leaves start to fall and stream water is still warm, although if strong floods occur this second potential primary production period may be short or non-existent (Ylla et al., 2007). This seasonal shift between inputs of allochthonous and autochthonous DOM (elevated primary production in spring and DOM and POM inputs in autumn) marks two important metabolically active periods in med-stream biofilms (Fig. 1). The first period is characterized by a greater development of algal biomass and the use of peptides and polysaccharides by the biofilm (as shown by increases in b-glucosidase and peptidase extracellular enzyme activities; Artigas et al., 2009) providing C and N sources for microbial heterotrophs. In autumn, the benthic heterotrophs (bacteria and fungi) became more relevant and there is a greater importance of plant material (cellulose, hemicellulose, lignin) in sustaining stream system functioning as indicated by the increase of cellulolytic and ligninolytic enzyme activities (Artigas et al., 2009). In winter, microbial activities decrease as a consequence of decreases in water temperature but biofilms still exhibit high ligninolytic activity (phenol oxidase and peroxidase activities) as in the late decomposition of autumn plant material (Artigas et al., 2004). Organic matter and biofilm metabolism during drought and rewetting episodes Although direct measurements of biofilm microbial metabolism during drought are scarce, the recovery after rewetting suggests that summer humid refuges are relevant for river functioning. When flow resumes and pools reconnect, the material is transported downstream, with the first water flush highly loaded in dissolved organic carbon and nutrients (Larned et al., 2010). This pulse of biodegradable high molecular weight organic matter is rapidly processed probably as a result of the activity of microbial heterotrophs (Romanı́ et al., 2006). During rewetting, the biofilm metabolism is responding rapidly specially in those microenvironments where humidity has been maintained during drought, such as in humid sediment patches and leaf litter (Amalfitano et al., 2008; Ylla et al., 2010). During 123 Hydrobiologia (2013) 719:43–58 the rewetting period, the majority of extracellular enzyme activities rapidly increase, indicating that these enzymes are important mechanisms for communities to recover after droughts (Romanı́ & Sabater, 1997; Zoppini & Marxsen, 2011). Flooding episodes also induce changes in the metabolic profile of microbial communities, probably as a result of the increase of allochthonous organic carbon and nutrients in the flowing water (Ylla et al., 2010). Zoppini et al. (2010) observed that b-glucosidase and lipase activities contribute substantially in metabolizing allochthonous materials during these periods. This general trend of fluctuations in biofilm microbial activity during drought and rewetting episodes is highly variable among different benthic substrata (fine or coarse sediment, cobbles, rocks, leaves, Fig. 1). The drought process amplifies the patchiness of metabolic hot spots as shown by the relationships between physical and chemical properties of sediments and the microbial extracellular enzyme activities from five temporary rivers of the Mediterranean Basin [Mulargia, Tagliamento and Candelaro (Italy), Krathis (Greece), Pardiela (Portugal)] (Zoppini et al., 2010; Zoppini & Marxsen, 2011; Casella, 2012). These sediments were characterized by their grain-size distribution, the concentrations of total organic carbon (TOC) and total nitrogen (TN, CHN analyzer), and ash-free dry weight (AFDW, subtracting the ash weight from the dry weight). These measurements were associated to the spectrofluorometric analyses of extracellular enzyme activities determined using artificial substrates (Zoppini et al., 2010). A canonical correspondence analysis (CCA; ter Braak & Verdonschot, 1995) was used to examine the relationships occurring between extracellular enzyme activities and physical–chemical properties of the analyzed sediments (Fig. 2). For this analysis, all data were logtransformed and elaborated by the PAST software package (PAlaeontological STatistics, ver. 2.05). The obtained Axis 1 explained 71% of variation of the extracellular enzyme activities, discriminating between fine and coarse sediments. The Axis 2 explained about 28% of the variation and discriminating between dry and wet conditions. Peptidase and phosphatase activities showed the highest contributions to total extracellular enzyme activities. Phosphatase activity is likely to be preferentially associated with sandy sediments (0.05–0.5 mm), while peptidase activity to coarse-grained sediments (2–0.5 mm). Hydrobiologia (2013) 719:43–58 Fig. 2 Canonical correspondence analysis (CCA) performed with log-transformed data of extracellular enzyme activities and physical–chemical properties of sediments collected from five temporary rivers of the Mediterranean Basin [Candelaro—Italy, Mulargia—Italy, Tagliamento—Italy, Kratis—Greece, Pardiela—Portugal (Zoppini et al., 2010; Zoppini & Marxsen, 2011; Casella, 2012)]. The arrowhead length is proportionally related to the vector length. The dot size is proportionally related to the percentage occurrence of each enzyme in the whole dataset. %WC water content, %AFDW ash-free dry weight, TN total nitrogen, TOC total organic carbon in sand, coarse, and fine sediments Peptidase discriminates environments with relatively low contribution of biofilm organic matter (AFDW, ash-free dry weight) and TN. The interpretation of the peptidase activity pattern is complex because it is an amphibolic enzyme potentially important in both carbon degradation and nitrogen acquisition. The predominance of peptidase in coarsegrained sediments has been observed in nutrient-poor habitats, where benthic microbial communities may rely on high peptidase activity to obtain sufficient amounts of organic nitrogen (Rusch et al., 2003). Peptidase activity has been also linked to the algal– bacterial relationship and the bacterial use of algal released peptides (Ylla et al., 2009), and thus a higher peptidase activity is often measured in coarse sand or cobbles where algal biomass develops (Artigas et al., 2009). Phosphatase activity is higher in sandy substrates with relatively higher TOC/AFDW ratios and lower water content. Moreover, this activity is likely to be scarcely affected by a progressive decrease in sediment–water content (Zoppini & Marxsen, 2011). 47 During the drought, a relevant phosphatase activity is maintained, especially in sediment biofilms (Timoner et al., 2012), probably indicating a significant phosphorus limitation for energy and cell maintenance by the microbial communities surviving the drought. b-glucosidase and lipase activities are associated with fine-wet sediments, with relatively lower TOC/ AFDW ratio where nutrients are available, as suggested by higher concentration of TN. High contribution of AFDW also allows us to infer the presence of a variety of organic substances probably rich in N and P. The interdependence observed between community respiration rates and the activity associated with lipase and b-glucosidase relies on the specificity of these enzymes to hydrolyze energy-rich compounds. The products of these enzyme activities (e.g., glycerol, fatty acids, and glucose) represent readily usable sources of energy fueling catabolic metabolism (Zoppini et al., 2010). Seasonality of enzyme activity ratios The heterotrophic biofilm capacity might be further analyzed from the perspective of the ‘‘ecoenzymatic stoichiometry’’ theory developed by Sinsabaugh et al. (2009) when the analysis of enzymes responsible for C, N and P decomposition compounds is included. Sinsabaugh et al. (2009) suggested that an equilibrium between C:N:P activity ratios of 1:1:1 indicates an equilibrium between the elemental composition of available organic matter, microbial biomass and nutrient assimilation, and growth of microorganisms in river sediments. Similarly, Sala et al. (2001) proposed that C:N:P activity ratios calculations are sensitive tools for detecting nutrient limitation in marine microbial communities. Long-term extracellular enzyme activities data collected in med-streams and rivers from Spain [Llobregat (Ricart et al., 2010), Ter (Romanı́ & Sabater, 1999), Fuirosos (Artigas et al., 2009; Ylla et al., 2010; Sabater et al., 2011), Solana (Romanı́ & Sabater, 1998), and Riera Major (Romanı́ & Sabater, 2001)] and from Italy [Mulargia and Candelaro (Zoppini et al., 2010; Zoppini & Marxsen, 2011; Casella, 2012)] were used to analyze the activity ratio between C:N, C:P, and N:P organic matter use in different types of biofilms (Fig. 3). In all these studies, the biofilm extracellular enzymes were measured by incubating fresh biofilm samples (between 3 and 5 replicates per site) with artificial 123 48 Hydrobiologia (2013) 719:43–58 Fig. 3 Relationship (in logarithms) between b-glucosidase and c peptidase (A), b-glucosidase and phosphatase (B), and peptidase and phosphatase (C) organic matter acquisition extracellular enzyme activities in microbial biofilms from Mediterranean Basin rivers. The solid line indicates a 1:1 relationship. Data include monthly or seasonal values obtained from the different streambed substrata available in each river (biofilms on cobbles and rocks, sand or leaves) including minimum 1 year of study. Data for the three relationships were obtained from four temporary rivers of the Mediterranean Basin [Llobregat—Spain (Ricart et al., 2010), Fuirosos—Spain (Artigas et al., 2009; Ylla et al., 2010; Sabater et al., 2011), Mulargia and Candelaro— Italy (Zoppini et al., 2010; Zoppini & Marxsen, 2011; Casella, 2012)]. Additional data of enzymatic activity from three Spanish temporary rivers [Ter (Romanı́ & Sabater, 1999), Solana (Romanı́ & Sabater, 1998), Riera Major (Romanı́ & Sabater, 2001)] were added on the b-glucosidase: phosphatase relationship (B). Differences between seasons (Spring, Summer, Autumn and Winter) are highlighted. The specific regression slopes and coefficients of variation for each relationship are included in Table 1 substrates followed by spectrofluorometric analysis (Romanı́ & Sabater, 2001). The relationships between C:N, C:P, and N:P acquiring enzymes were calculated after logarithmic transformation of the data and performing linear regression analyses in order to calculate the slope and coefficient of variation (Sigma Plot Ver. 11.0, Systat Software, Inc.; CA, USA). In the analyzed med-stream biofilms, the equilibrium was observed for peptidase:phosphatase activity ratios (N:P, slope = 1:1), but not for the b-glucosidase:peptidase (C:N) and b-glucosidase:phosphatase (C:P) activity ratios (Fig. 3; Table 1). Overall, the b-glucosidase:peptidase and b-glucosidase:phosphatase ratios were below the 1:1 equilibrium, indicating a greater potential of med-stream biofilms to acquire N and P than C. Specifically, the shifts of enzyme activity ratios were more pronounced during spring and winter (ranging 0.6–0.7:1), suggesting that the greatest N and P limitation occurred during these periods. Conversely, the highest variability in enzyme activity ratios was observed during the summertime (C:N and C:P variation coefficients ranging from 44 to 49%, Table 1). This variability in organic matter acquisition may be explained by the important changes in organic matter availability during drought episodes (Ylla et al., 2010). As an example, an unbalanced C:N activity ratio (1.7–2:1) was observed during the summer– autumn episode of 2006 in the Fuirosos stream, indicating a greater acquisition of organic C than N under dry conditions (Fig. 3A, white and dark-gray symbols far above the 1:1 line). Here, the increased 123 water stress in the riparian forest causing late summer litter fall and the POM accumulation in pools may be responsible for the enhanced organic C acquisition. The above results suggest that in med-rivers, the heterotrophic use of organic compounds is unbalanced by the greater use of phosphorus and peptides, probably indicating a limitation of nitrogen and phosphorus at least during some periods of the year. The stoichiometry analysis also shows that the relationship between enzyme capabilities can drastically Hydrobiologia (2013) 719:43–58 49 Table 1 Enzyme activity ratio calculations for b-glucosidase: peptidase (Glu: Pep), b-glucosidase: phosphatase (Glu: Phos) and peptidase: phosphatase (Pep: Phos) organic matter acquisition activities in various temporary rivers of the Mediterranean region [Llobregat—Spain (Ricart et al., 2010), Fuirosos— Glu:Pep Spain (Artigas et al., 2009; Ylla et al., 2010; Sabater et al., 2011), Mulargia and Candelaro—Italy (Zoppini et al., 2010; Zoppini & Marxsen, 2011; Casella, 2012), Ter (Romanı́ & Sabater, 1999), Solana (Romanı́ & Sabater, 1998), Riera Major, (Romanı́ & Sabater, 2001)] Glu:Phos Pep:Phos Slope CV Slope CV Slope CV All data 0.8:1 42.6 0.8:1 42.3 1:1 17.4 Spring 0.6:1 31.7 0.7:1 37.8 1:1 15 Summer 0.9:1 44.5 0.9:1 49.4 1:1 16.5 Autumn 0.9:1 36 0.8:1 33 1:1 20.2 Winter 0.7:1 24.5 0.7:1 29.7 1:1 11.7 Regression slopes and coefficients of variation (italics) for each enzyme activity ratio were represented for the whole year (all) and between seasons (spring, summer, autumn, winter) change between seasons and substrata, such as the much higher use of polysaccharides (high b-glucosidase, acquiring a C source) than peptidase in a temporal med-stream (the Fuirosos) during the summer period (Fig. 3). This behavior not only underlines the mediterranean characteristic of ‘‘fluctuations’’ but also the adaptation of the microbial biofilm communities to the available organic matter sources. Thus, organic matter supply in med-streams is strongly pulsed and this finally determines the organic matter use in biofilms. Resistance to drought: the response of the heterotrophic component of microbial biofilms The maintenance of the stream functioning in a medstream affected by severe drought episodes is linked to the survival of the heterotrophic component of microbial biofilms. The resistance and survival to drought and rewetting episodes could determine the development of a specific distinctive bacterial community. In med-streams, sediment and leaf material Table 2 Quantitative occurrence of major bacterial taxa retrieved within the benthic substrates based on fluorescence in situ hybridization Proteobacteria (ALF968, BET42a, GAM42a), Bacteroidetes (e.g., CF319a) and Gram-positive bacteria (e.g., HGC69a, LGC354abc). Values are averages from 38 samples collected from 8 Mediterranean streams [Cremera—Italy (Amalfitano & Fazi, 2008; Bandiera 2006); Mulargia—Italy, Tagliamento—Italy, Kratis—Greece, Pardiela—Portugal (Amalfitano et al., 2008; Zoppini et al., 2010); Albegna, Ente and Fiora—Italy (Fazi et al., 2005)] 1 9 105cells/g, s 1 9 106cells/g, 1 9 107cells/g, d 1 9 108 cells/g, m 1 9 109 cells/g 123 50 123 1,0 %AFDW <0.2mm Firmicutes Actinobacteria %WC 0,5 Axis 2 (30%) are where the moist conditions might be more easily maintained, providing a refuge in which aquatic bacterial communities could survive in contrast to the more harsh conditions in cobble biofilms (Ylla et al., 2010). The response to water stress of microbial communities in soil (Van Gestel et al., 1992; Steenwerth et al., 2003; Fierer et al., 2003; Wu & Brookes, 2005; Williams, 2006) or freshwater sediment (Amalfitano et al., 2008; Fazi et al., 2008; Marxsen et al., 2010) has been mainly studied in microcosm experiments. Some studies showed changes in microbial diversity in natural streambed sediments subject to hydrological fluctuations (Rees et al., 2006; Zoppini et al., 2010). Using a qualitative DNA-based approach, some authors (Lueders & Friedrich, 2000; Marxsen et al., 2010) showed community changes in sediments in response to rewetting, while Fierer et al. (2003) reported that the drying and rewetting cycle affects the microbial community structure, mainly in soils that underwent moisture stress infrequently. A strong relation between bacterial community and substratum characteristics (i.e., water and organic matter content) is evident when comparing quantitative data from eight temporary med-streams (Table 2). The highest bacterial abundance was found on organic matter-rich allochthonous leaf accumulations and, as expended, the lowest values on intra-sediment biofilms under dry conditions. The detritus accumulated in stagnant waters showed a relatively high organic matter content, mainly originating from allochthonous inputs at an advanced stage of decomposition and by in situ production. This substratum in pools supports an abundant microbial community, thus acting as a ‘‘humid refuge’’ for aquatic microbes. From a wide range of freshwater ecosystems, fluorescence in situ hybridization (FISH) studies suggested that there were some crucial differences among bacterial assemblages associated with different sediment and detritus types, even at a broad phylogenetic level (Fazi et al., 2005; Gao et al., 2005; Marxsen et al., 2010). In med-streams multiple factors affect the bacterial community composition (Fazi et al., 2005, 2008; Zoppini et al., 2010), and it is evident that different bacterial domains show different distribution patterns (Table 2). Following the protocol optimized by Fazi et al. (2007), bacterial community composition was assessed by FISH in sediments from five selected med-streams [Cremera— Italy (Bandiera, 2006; Amalfitano and Fazi, 2008); Hydrobiologia (2013) 719:43–58 Cytophaga-Flavobacteria Alphaproteobacteria >2.0mm 0,0 0.2-0.5mm Gammaproteobacteria Betaproteobacteria -0,5 0.5-2.0mm -1,0 -1,0 -0,5 0,0 0,5 1,0 1,5 Axis 1 (52%) Fig. 4 Canonical correspondence analysis (CCA) performed with log-transformed data of major bacterial taxa and the grain size classes, water, and organic matter content of the sediments collected from five temporary rivers of the Mediterranean Basin [Cremera—Italy (Amalfitano and Fazi, 2008; Bandiera 2006); Mulargia—Italy, Tagliamento—Italy, Kratis—Greece, Pardiela—Portugal (Amalfitano et al., 2008; Zoppini et al., 2010)]. %WC water content, %AFDW ash-free dry weight, TN total nitrogen, TOC total organic carbon; \0.2 mm: ultra-fine grain size; 0.2–0.5 mm: fine grain size; 0.5–2.0 mm medium grain size; [2.0 mm: coarse grain size Mulargia—Italy, Tagliamento—Italy, Kratis—Greece, Pardiela—Portugal (Amalfitano et al., 2008; Zoppini et al., 2010)]. A CCA was used to examine the preferential associations of major bacterial taxa with the grain size classes, and water and organic matter content of the sediments. The number of cells per taxon was logarithmically transformed (ter Braak & Verdonschot, 1995). Differences in environmental factors explained about 52 and 30% of the variation in the bacterial community for Axis 1 and Axis 2, respectively. The results show that in the sediments of the analyzed medstreams, the spatial and temporal dynamics of microbial phylogenetic groups are affected by grain size distribution (Fig. 4), and thus, regulated by the frequency and intensity of the water intermittency. The mechanisms by which the stream flow dictates the sediment grain size patterns are fundamental to organic matter and nutrient dynamics and, thus, to bacterial community structuring in intra-sediment biofilms (Santmire & Leff, 2007). The grain size distribution depends largely upon the interlocking of individual particles of different Hydrobiologia (2013) 719:43–58 size, the near-bed flow characteristics, the longitudinal slope, and the prevailing sediment transport conditions (Hendrick et al., 2010). In med-regions, the strong hydrologic seasonality and the drought severity determine the degree of disruption of the longitudinal fluvial continuum (Butturini et al., 2003), representing additional determinants of the sediment accumulation processes on the streambed (Wittenberg, 2002). Overall, the Alpha, Beta, and Gamma subclasses of Proteobacteria accounted for the major fraction of the domain bacteria that colonize the benthic substrates. The presence of a large fraction of Betaproteobacteria was reported at sites with high benthic organic matter content (Wobus et al., 2003; Gao et al., 2005). This could be attributed to their high efficiency in oxidizing ammonia and degrading organic compounds in association with specific enzymatic activities (Araya et al., 2003; Kirchman et al., 2004; Zoppini et al., 2010). Moreover, they are reported to be an active component of freshwater microbial communities in sediments exposed to hydrological fluctuations (Amalfitano et al., 2008; Besemer et al., 2009b; Marxsen et al., 2010; Zoppini et al., 2010) and in biofilms during the early succession stages (Brümmer et al., 2003; Lupini et al., 2011). The Alphaproteobacteria generally showed a lower abundance than the Beta subclass, but in some cases, they are reported to lead the transformation processes of labile organic materials and to out-compete other groups in mature biofilms, being highly efficient in nutrient assimilation and substrate mineralization (Santmire & Leff, 2007). The members of Gammaproteobacteria are reported to be relatively abundant in presence of a high nutrient concentration and when extra organic matter input and humic substances become available (Wobus et al., 2003; Gao et al., 2005; Zoppini et al., 2010). According to previous reports, the increase in bacteria from the Cytophaga-Flavobacteria (CF) group in substrates highly loaded with organic carbon may be a general feature of microbial communities in freshwater habitats (Salcher et al., 2010). Some members of the CF cluster are specialized for the degradation of complex macromolecules (Kirchman, 2002; Tamaki et al., 2003). Accordingly, they constitute a significant proportion of the microbial communities on substrates characterized by recalcitrant and high molecular weight DOM and on suspended particles either in stream or river biofilms (Simon et al., 2002; O’Sullivan et al., 2004). 51 The quantitative occurrence of Gram-positive bacteria in stream bed substrates is under-investigated. Generally, the members of the polyphyletic groups of Actinobacteria (cells with a high DNA content of guanine and cytosine) and Firmicutes (cells with a low DNA content of guanine and cytosine) are at least one or even two order of magnitude lower than those of the taxa above described. In some local cases, the Actinobacteria appear to be associated with high abundance of cells belonging to the Betaproteobacteria (Salcher et al., 2010). Moreover, they could constitute an important fraction of the community in dry sediments, suggesting a high molecular and metabolic resistance to desiccation (Amalfitano et al., 2008). Many members of the Firmicutes (e.g., Bacillus spp.) are known to be spore-forming and, thus, were reported as the first colonizers of the water column after sediment desiccation (Fazi et al., 2008). Resistance to drought: the response of autotrophic component of microbial biofilms The river biofilms developing on the upper side of rocks and cobbles and the surface sediment support a great proportion of autotrophic biomass (up to 80–90% of whole biofilm biomass; Romanı́, 2010). In med-streams, drought requires specific structural and physiological adaptations from autotrophic microorganisms to survive, as well as particular recolonization abilities once the drought is over. Factors to be considered start from the cellular level but eventually involve the whole response of autotrophs to the reach and segment scale during drought. Periods of low or non-flow lead to water loss for primary producers, and desiccation stress (Mosisch, 2001). Several studies point out the resistance of the autotrophic community to drought (Romanı́ & Sabater, 1997; Robson & Matthews, 2004; Caramujo et al., 2008; Robson et al., 2008). This is based on structural properties (higher EPS—extracellular polymeric substances—content, species succession, resistance structures), but also on physiological properties (light-shade adaptability, photosynthetic activity after rewetting). Some groups and species are better adapted than others (Kawecka, 2003; Robson & Matthews, 2004; Ledger et al., 2008) to drought. Some have cellular or other supraorganismic structures that provide shelter 123 52 to desiccation. Cyanobacteria and green algae are better adapted to withstand drought than are diatoms. Some Cyanobacteria in calcareous environments deposit carbonates, while others produce stromatolitic-like mats that provide protection to the cells living inside, as well as a high porosity prone to rewetting soon after rains occur (Sabater et al., 2000). These structures show quick autotrophic (and heterotrophic) response after rewetting (Romanı́ & Sabater, 1997). Among the common genera building (and dwelling) on those structures are Rivularia, Phormidium, Homoeothrix, or Schizothrix. Other crust-forming species also resist drought rather well. For example, the green alga Gongrosira persists after long desiccation, but it has been observed experimentally (Ledger et al., 2008) that its numbers may largely decrease after drought. Algal communities experience succession in the process from low flow to drought. In a reach scale, there is transition from diatom mats to encrusting forms as dryness progresses (Romanı́ & Sabater, 1998; Ledger et al., 2008). Diatoms are less resistant than other groups to desiccation. Still, some produce thick mucilaginous masses that may act as protectors of the living cells, at least during shorter droughts. Among these, the genera Cymbella and Gomphonema include several mucilage-forming species, which occur in med-streams during late spring and summer. Other diatoms build inner plates to resist desiccation and osmotic variations related to alternate drought and rewet. These are organisms which also subsist in subaerial environments (Sabater, 2009). Navicula contenta, Fragilaria construens, Achnanthes lanceolata, and Denticula tenuis persist under these conditions, and are common in med-rivers (Tornés & Sabater, 2010). Other algae also possess thick cell walls that protect the cell from desiccation. The red alga Hildenbrandia rivularis produces permanent crusts mostly in poorly lit areas of oligotrophic streams that resist long desiccation and return to activity after the flow returns. Some filamentous green algae (Spirogyra, Zygnema, and other Zygnematales and Oedogoniales) produce zygospores through sexual reproduction that are thickwalled and become dormant to survive adverse conditions such as drought. These filamentous forms are adapted to shrinking water conditions. Zygnematales grow unattached to the substrata (except a few, such as Spirogyra fluviatilis; Margalef, 1983) and form large masses in slow-moving areas, and are 123 Hydrobiologia (2013) 719:43–58 well-adapted to excess light. During the development of drought conditions, cells may become yellowish, and although some may have impaired their photosynthetic apparatus, the mass itself is able to persist and adapts to use nutrients efficiently (Borchardt, 1994). During these conditions, masses may be able to affect nearby water temperature, as well as pH, and therefore exert influence on local biogeochemistry. Surprisingly some of these assumptions remain unmeasured. It is also remarkable that within these masses multiple species co-exist and hybridization is common. Oedogonium and Zygnematales are polyploid, and therefore able to face the potential genetic drift that derives from multiple hybridization (Margalef, 1983). Finally, some other green algae (Cladophora or Stigeoclonium) possess differentiated basal cells (rizoids) that not only secure attachment, but also persist after the plant has completed its cycle (Margalef, 1983). This helps to explain its widespread occurrence in drought-prone med-rivers after water recovery. There is a reduction in chlorophyll a with the flow drawback (Ylla et al., 2010). Streambed materials remain exposed to high temperatures and high incident light conditions particularly in open areas that affect the photosynthetic apparatus. Algal cells are metabolically inactive during dry conditions, and the return of photosynthetic activity is only known for some groups of organisms. The return may be fast in stromatolitic biofilms, where photosynthesis was noticeable 1 h after rewetting in a recovery experiment (Romanı́ & Sabater, 1997). Also, terrestrial cyanobacteria recover their photosynthetic efficiencies extremely fast, from minutes to a few hours (Scherer et al., 1984). However, the photosynthetic recovery of epilithic diatoms or green algae to complete drought is unknown. Adaptations to progressive drought conditions are better known. Lower photosynthetic efficiencies during low flow in a medstream were associated with the carotenoid accumulation in sun-adapted biofilms (Guasch & Sabater, 1995), which provide photooxidative protection to photoinhibition at summer ambient irradiances (Scherer et al., 1988; Quesada et al., 1995; Dieser et al., 2010). UVprotective pigments such as carotenoids, xanthophylls, and scytonemin accumulate in microbial mats (Fernández-Valiente et al., 2007) and soil crust biofilms (Belnap et al., 2007). It may be that physiological adjustments of autotrophic cells to cope with high temperatures and exposure to extreme solar radiation also occur under drought episodes. These physiological Hydrobiologia (2013) 719:43–58 adjustments may allow the cells to allocate more energy to processes other than protecting the cell from light and temperature, and makes it adaptive to better withstand desiccation stress (Fleming & Castenholz, 2007) and facilitate physiological recovery. Recolonization ability of autotrophs is related to two main factors. The first is related to the speed at which drought occurs. The rapidity of drying matters, because slow drying enables longer permanence of refuges that allows more possibilities for the organisms to survive (time for structural and physiological adaptations), as well as for regrowth (Robson et al., 2008). The severity of drought is essential in defining the existence or otherwise of these refuges, and this depends on the specific location of the site (altitude or topography, local climate, relevance of water abstraction). The second is the dominant type of substrata, i.e., the prevalence of sediments, wood, or cobbles in the streambed that have different potentials to maintain humidity and enable host recolonization. Sediments are the most favorable habitat under complete desiccation conditions. Areas underneath cobbles may also allow for humid conditions, where cells can survive. With sufficient humidity, these areas may host live cells or resting stages, which are essential to recolonization. Perennial pools, or small areas of superficial flow, provide a refuge from which to restart colonization. Perennial pools may guarantee the sufficient inoculum to restart colonization downstream. Density of algae for regrowth is positively related to the water permanence in the stream (Robson & Matthews, 2004). However, Robson et al. (2008) showed that the main refuge source is the substrata type, and that pools are not contributing significantly to the overall recolonization. The algal flora developing on pools does not match that colonizing flowing surface waters, and additional sources (suitable substrata) are required to complete the recolonization. On top of these factors, algae show different recolonization abilities. Diatoms quickly colonize open spaces that are opened by disturbances. At the reach scale, areas temporarily rewet and again dried provide unsuitable substrata for autotrophs. However, some diatoms may use these areas to initiate pioneer communities (Tornés & Sabater, 2010). The frequency of habitat emersion and autotrophs development is patch-specific, and may lead to high spatial differences in algal diversity and community composition within short transactional distances (Tornés & Sabater, 2010). 53 Finally, the higher capacity of algae to recover its metabolism as a result of physiological adjustments produces high productivity immediately after rewetting (Dodds et al., 1996; Romanı́ & Sabater, 1997), despite lower concentrations of chlorophyll a. The temporal extent of intermittency may substantially reduce algal productivity resulting from the loss of drought refuges (Robson & Matthews, 2004) and severe damage to algal cells that may hinder the recovery. This fact may limit the supply of both autochthonous carbon (Dodds et al., 1996) and allochthonous carbon, because it has been demonstrated that algal photosynthesis enhances heterotrophic metabolism, stimulating extracellular enzyme activities (Francoeur & Wetzel, 2003; Romanı́ et al., 2004b; Francoeur et al., 2006). Therefore, the whole ecosystem metabolism may be affected. Adaptation to windows of opportunity for regrowth is essential; production pulses may supply food webs with high quality carbon (Artigas et al., 2009). Comparing stream biofilms from mediterranean to non-mediterranean climate regions The data and literature reviewed in this manuscript as well as some specific studies focusing on the comparison between stream biofilms from mediterranean and non-mediterranean regions highlight some distinctive structural and functional features of mediterranean ones. When comparing the changes during biofilm formation in a med-stream in contrast to a Central European stream (third-order forested streams, Artigas et al., 2012), a faster colonization by algae and bacteria was measured at the med-stream although reaching similar biomass values at the mature biofilm. Also, med-river biofilms tend to have a greater content of extracellular polymeric substances (Artigas et al., 2012), which might be linked to the adaptation to drought and the development of species producing mucilage (cyanobacteria, diatoms). Chlorophyll density was more fluctuating in a forested med-stream (with higher values in spring-early summer) while it was more constant over the year in an Atlantic stream (Sabater et al., 2008). For the bacterial community, it is suggested that the hydrologic seasonality of medrivers, which change the physico-chemical features of benthic substata, indirectly affects the occurrence and the abundance of the major bacterial groups, and is mainly linked to water and organic matter availability. 123 54 When rewetted streambed sediments from two low order streams in distinct climate regions (a Central European and a Mediterranean), a lower bacterial biomass and lower bacterial production were measured at the med-stream (Marxsen et al., 2010). In the same study, bacterial diversity (as measured by TGGE analysis) was similar for both streams in dry sediments but it was lower in Mediterranean sediments after rewetting. Those results suggested that bacterial community composition is more fluctuating in med than in non-med-streams. Under more extreme hydrologic conditions than medstreams, desert streams show some similarities in biofilm structure and functioning. Zeglin et al. (2011) found that changes in bacterial community composition and diversity were mainly affected by sediment water content and conductivity. In microbial mats from a desert stream, flooding resulted in the replacement of over 74% of the microbial community (bacteria and algae; Abed et al., 2011). It could be hypothesized that in desert streams the microbial community is replaced after flooding in a much higher degree than that occurring in med-streams because of the lack of persistent humid refuges. In the case of algal biomass, it is generally described that during drought there is a decrease in organic inputs in contrast to inorganics enhancing autotrophy, as observed in a Central New Mexico stream (Dahm et al., 2003). However, in med-streams this increase in autotrophy is not clear and likely depends on the development of the riparian vegetation and the leaf fall that may occur in intense summer drought. In a forested med-stream, a decrease in chlorophyll content on the biofilm developing on sand and cobbles was measured during the wet to drought process (Ylla et al., 2010) as well as an increase in the heterotrophic biomass (fungi and bacteria, Artigas et al., 2009). When comparing seasonal data of three med-rivers to nine Atlantic rivers (from 1 to 4 order size, including open and forested and eutrophic and oligotrophic ecosystems) a higher bacterial to algal biomass ratio was shown for the Mediterranean biofilms (Romanı́ & Sabater, 2000) suggesting a higher heterotrophy (Fig. 1). The biofilm use of the available organic matter also shows specific features when compared to nonmed-rivers as shown by the results of biofilm extracellular enzyme activities. From the comparison of seasonal data from med- to Atlantic rivers (Romanı́ & Sabater, 2000), a significant higher polysaccharide decomposition capacity was measured for the med- 123 Hydrobiologia (2013) 719:43–58 river biofilms (higher b-glucosidase and b-xylosidase), suggesting an effect of temperature and/or of a different microbial community colonizing the substrata. However, a specific study of the effect of drought/rewetting showed a lower polysaccharide decomposition capacity (as well as peptide) at the med-stream after rewetting, which was not observed in the non-Mediterranean stream. This result was linked to a more intense drying in the med-stream (Marxsen et al., 2010). Conclusions, trends, and perspectives Hydrology appears as one of the main factors affecting the biofilm structure and functioning. In the case of the biofilm autotrophs, the structural and physiological adaptations to drought are well known; much less is known about the effect of such physiological changes on the water quality or the effect of floods and biofilm recolonization. In the case of the biofilm heterotrophs, although some data are provided here about the bacterial community composition, there are few studies analysing the bacterial community during drought and rewetting episodes. The processes taking place in the sediment during the drought may be also very relevant for the resistance and recovery during rewetting. Linking both the autotrophs and heterotrophs there is a need for research at different times but especially on different spatial scales that take into account the effect of patchiness. The specific conditions at different but short time and spatial scales may have a great effect on biofilm structure and functioning. Experiments linking laboratory and field work including such patchiness are needed. Finally, although one may consider that medstream biofilms are adapted to drought and floods, and efficiently make use of the available organic matter pulses, the question about how efficient these communities actually are in decomposing organic matter still remains unanswered. Further research in analyzing the increasing frequency and intensity of drought/flooding episodes, and their impact on biofilm extracellular enzyme activities and biofilm architecture, could shed some light on understanding biofilm processes. The fluctuations in microbial biomass and in enzyme activities suggest that efficiencies are also fluctuating, because in the rewetting there is a biomass decrease but some activities are increased. Hydrobiologia (2013) 719:43–58 Acknowledgments This study was funded by the projects CGL2011-30151-C02-01, and SCARCE (Consolider-Ingenio 2010 CSD2009-00065) of the Spanish Ministry of Economy and Competitiveness; the Italy–Spain Exchange Project CNR-CSIC 2006IT0010; and the EU project MIRAGE (FP7-ENV-2007-1 n.211732). We also thank the comments from two anonymous reviewers as well as editors’ suggestions. References Abed, R. M. M., S. Al Kindi, A. Schramm & M. J. Barry, 2011. Short-term effects of flooding on bacterial community structure and nitrogenase activity in microbial mats from a desert stream. Aquatic Microbial Ecology 63: 245–254. Acuña, V., I. Muñoz, A. Giorgi, M. Omella, F. Sabater & S. Sabater, 2005. Drought and postdrought recovery cycles in an intermittent Mediterranean stream: structural and functional aspects. Journal of the North American Benthological Society 24: 919–933. Acuña, V., A. Giorgi, I. Munoz, F. Sabater & S. Sabater, 2007. Meteorological and riparian influences on organic matter dynamics in a forested Mediterranean stream. Journal of the North American Benthological Society 26: 54–69. Amalfitano, S. & S. Fazi, 2008. Recovery and quantification of bacterial cells associated with streambed sediments. Journal of Microbiological Methods 75: 237–243. Amalfitano, S., S. Fazi, A. Zoppini, A. Barra Caracciolo, P. Grenni & A. Puddu, 2008. Responses of benthic bacteria to experimental drying in sediments from Mediterranean temporary rivers. Microbial Ecology 55: 270–279. Araya, R., K. Tani & T. Takag, 2003. Bacterial activity and community composition in stream water and biofilm from an urban river determined by fluorescent in situ hybridization and DGGE analysis. FEMS Microbiology Ecology 43: 111–119. Artigas, J., A. M. Romanı́ & S. Sabater, 2004. Organic matter decomposition by fungi in a Mediterranean forested stream: contribution of streambed substrata. Annales de Limnologie 40: 269–277. Artigas, J., A. M. Romanı́, A. Gaudes, I. Muñoz & S. Sabater, 2009. Benthic structure and metabolism in a Mediterranean stream: from biological communities to the whole stream ecosystem function. Freshwater Biology 54: 2025–2036. Artigas, J., K. Fund, S. Kirchen, S. Morin, U. Obst, A. M. Romanı́, S. Sabater & T. Schwartz, 2012. Patterns of biofilm formation in two streams from different bioclimatic regions: analysis of microbial community structure and metabolism. Hydrobiologia 695: 83–96. Bandiera, G., 2006. Caratterizzazione della comunità microbica associata a diversi substrati in ambiente fluviale: tecniche molecolari per lo studio della diversità. Master thesis, Università degli Studi Roma 3: 92 pp [available on internet at http://www.parcodiveio.it/_ita/servizi/_doc/analisi/tesi_ Bandiera_07.pdf]. Belnap, J., S. L. Phillips & S. D. Smith, 2007. Dynamic of cover, UV-protective pigments, and quantum yield in biological soil crust communities of an undisturbed Mojave Desert shrubland. Flora 202: 674–686. 55 Benfield, E. F., 1997. Comparison of litterfall input to streams. Journal of North American Benthological Society 16: 104–108. Bernal, S., A. Butturini & F. Sabater, 2005. Seasonal variation in dissolved nitrogen and DOC:DON ratios in an intermittent Mediterranean stream. Biogeochemistry 75: 351–372. Bertilsson, S. & J. B. J. Jones, 2003. Supply of dissolved organic matter to aquatic ecosystems: autochthonous sources. In Findlay, S. E. G. & R. L. Sinsabaugh (eds), Aquatic Ecosystems. Interactivity of Dissolved Organic Matter. Academic Press, San Diego: 4–24. Besemer, K., G. Singer, I. Höd & T. J. Battin, 2009a. Bacterial community composition of stream biofilms in spatially variable-flow environments. Applied and Environmental Microbiology 75: 7189–7195. Besemer, K., I. Hodl, G. Singer & T. J. Battin, 2009b. Architectural differentiation reflects bacterial community structure in stream biofilms. ISME Journal 3: 1318–1324. Borchardt, M. A., 1994. Effects of flowing water on nitrogenand phosphorus-limited photosynthesis and optimum N:P ratios by Spirogyra fluviatis (Charophyceae)1, 2. Journal of Phycology 30: 418–430. Bott, T. L., L. A. Kaplan & F. T. Kuserk, 1984. Benthic bacterial biomass supported by streamwater dissolved organic matter. Microbial Ecology 10: 335–344. Brümmer, I. H. M., A. Felske & I. Wagner-Döbler, 2003. Diversity and seasonal variability of b-proteobacteria in biofilms of polluted rivers: analysis by temperature gradient gel electrophoresis and cloning. Applied and Environmental Microbiology 69: 4463–4473. Butturini, A., S. Bernal, C. Hellin, E. Nin, L. Rivero, S. Sabater & F. Sabater, 2003. Influences of the stream groundwater hydrology on nitrate concentration in unsaturated riparian area bounded by an intermittent Mediterranean stream. Water Resources Research 39: 1110. Caramujo, M. J., C. R. B. Mendes, P. Cartaxana, V. Brotas & M. J. Boavida, 2008. Influence of drought on algal biofilm and meiofaunal assemblages of temperate reservoirs and rivers. Hydrobiologia 598: 77–94. Casella, P., 2012. Studio delle comunità microbiche in sedimenti di ecosistemi fluviali temporanei: l’effetto delle diverse fasi idrologiche sul flusso dei nutrienti e sul destino dei microinquinanti organici. PhD Thesis, University of Tuscia, Department of Ecological and Biological Sciences, Viterbo. Chan, M., K. Moser, J. M. Davis, G. Southam, K. Hughes & T. Graham, 2005. Desert potholes: ephemeral aquatic microsystems. Aquatic Geochemistry 11: 279–302. Dahm, C. N., M. A. Baker, D. I. Moore & J. R. Thibault, 2003. Coupled biogeochemical and hydrological responses of streams and rivers to drought. Freshwater Biology 48: 1219–1231. Dı́az Villanueva, V., J. Font, T. Schwartz & A. M. Romanı́, 2011. Biofilm formation at warming temperature: acceleration of microbial colonization and microbial interactive effects. Biofouling 27: 59–71. Dieser, M., M. Greenwood & C. M. Foreman, 2010. Carotenoid pigmentation in antarctic heterotrophic bacteria as a strategy to withstand environmental stresses. Artic, Antarctic, and Alpine Research 42: 396–405. 123 56 Dodds, W. K., R. E. Hutson, A. C. Eichem, M. A. Evans, D. A. Gudder, K. M. Fritz & L. Gray, 1996. The relationship of floods, drying, flow and light to primary production and producer biomass in a prairie stream. Hydrobiologia 333: 151–159. Fazi, S., S. Amalfitano, J. Pernthaler & A. Puddu, 2005. Bacterial communities associated with benthic organic matter in headwater stream microhabitats. Environmental Microbiology 7: 1633–1640. Fazi, S., S. Amalfitano, I. Pizzetti & J. Pernthaler, 2007. Efficiency of fluorescence in situ hybridization for bacterial cell identification in temporary river sediments with contrasting water content. Systematic and Applied Microbiology 30: 463–470. Fazi, S., S. Amalfitano, C. Piccini, A. Zoppini, A. Puddu & J. Pernthaler, 2008. Colonization of the overlying water by bacteria from dry river sediments. Environmental Microbiology 10: 2760–2772. Fernández-Valiente, E., A. Camacho, C. Rochera, E. Rico, W. F. Vincent & A. Quesada, 2007. Community structure and physiological characterization of microbial mats in Byers Peninsula, Livingston Island (South Shetland, Antarctica). FEMS Microbiology Ecology 59: 377–385. Fierer, N., J. P. Schimel & P. A. Holden, 2003. Influence of drying–rewetting frequency on soil bacterial community structure. Microbial Ecology 45: 63–71. Fisher, S. G. & G. E. Likens, 1973. Energy flow in Bear Brook, New Hampshire: an integrative approach to stream ecosystem metabolism. Ecology 43: 421–439. Fleming, E. D. & R. W. Castenholz, 2007. Effects of periodic desiccation on the synthesis of the UV-screening compound, scytonemin, in cyanobacteria. Environmental Microbiology 9: 1448–1455. Francoeur, S. N. & R. G. Wetzel, 2003. Regulation of periphytic leucine-aminopeptidase activity. Aquatic Microbial Ecology 31: 249–258. Francoeur, S. N., M. Schaecher, R. K. Neely & K. A. Kuehn, 2006. Periphytic photosynthetic stimulation of extracellular enzyme activity in aquatic microbial communities associated with decaying typha litter. Microbial Ecology 52: 662–669. Gao, X., O. A. Olapade & L. G. Leff, 2005. Comparison of benthic bacterial community composition in nine streams. Aquatic Microbial Ecology 40: 51–60. Gasith, A. & V. H. Resh, 1999. Streams in Mediterranean climate regions: abiotic influences and biotic responses to predictable seasonal events. Annual Review of Ecology and Systematics 30: 51–81. Graça, M. A. S., 1993. Patterns and processes in detritus-based stream systems. Limnologica 23: 107–114. Guasch, H. & S. Sabater, 1995. Seasonal variations in photosynthesis-irradiance responses by biofilms in Mediterranean streams. Journal of Phycology 31: 727–735. Hendrick, R. R., L. L. Ely & A. N. Papanicolaou, 2010. The role of hydrologic processes and geomorphology on the morphology and evolution of sediment clusters in gravel-bed rivers. Geomorphology 114: 483–496. Joffre, R., G. I. Agren, D. Gillon & E. Bosatta, 2001. Organic matter quality in ecological studies: theory meets experiment. Oikos 93: 451–458. Jones, J. B. & L. A. Smock, 1991. Transport and retention of particulate organic matter in two low-gradient headwater 123 Hydrobiologia (2013) 719:43–58 streams. Journal of the North American Benthological Society 10: 115–126. Kaplan, L. A. & T. L. Bott, 1989. Diel fluctuations in bacterial activity on streambed substrata during vernal algal blooms: effects of temperature, water chemistry and habitat. Limnology and Oceanography 34: 718–733. Kaplan, L. A. & J. D. Newbold, 1995. Measurement of streamwater biodegradable dissolved organic carbon with a plug-flow bioreactor. Water Research 29: 2696–2706. Kawecka, B., 2003. Response to drying of cyanobacteria and algae communities in Tatra Mts stream (Poland). Oceanological and Hydrobiological Studies 32: 27–38. Kirchman, D. L., 2002. The ecology of Cytophaga-Flavobacteria in aquatic environment. FEMS Microbiology Ecology 39: 91–100. Kirchman, D. L., A. I. Dittel, S. E. G. Findlay & D. Fischer, 2004. Changes in bacterial activity and community structure in response to dissolved organic matter in the Hudson River, New York. Aquatic Microbial Ecology 35: 243–257. Larned, S. T., T. Datry, D. B. Arscott & K. Tockner, 2010. Emerging concepts in temporary-river ecology. Freshwater Biology 55: 717–738. Ledger, M. E., R. M. L. Harris, P. D. Armitage & A. M. Milner, 2008. Disturbance frequency influences patch dynamics in stream benthic algal communities. Oecologia 155: 809–819. Lueders, T. & M. Friedrich, 2000. Archaeal population dynamics during sequential reduction processes in rice field soil. Applied and Environmental Microbiology 66: 2732–2742. Lupini, G., L. Proia, M. Di Maio, S. Amalfitano & S. Fazi, 2011. CARD-FISH and confocal laser scanner microscopy to assess successional changes of the bacterial community in freshwater biofilms. Journal of Microbiological Methods 86: 248–251. Margalef, R., 1983. Limnologı́a. Omega, Barcelona. Marxsen, J., A. Zoppini & S. Wilczeck, 2010. Microbial communities in streambed sediments recovering from desiccation. FEMS Microbiology Ecology 71: 374–386. McDonald, S., A. G. Bishop, P. D. Prenzler & K. Robards, 2004. Analytical chemistry of freshwater humic substances. Analytica Chimica Acta 527: 105–124. McIntyre, R. E. S., M. A. Adams, J. F. Douglas & P. F. Grierson, 2009. Rewetting and litter addition influence mineralisation and microbial communities in soils from a semi-arid intermittent stream. Soil Biology & Biochemistry 41: 92–101. Mosisch, T. D., 2001. Effects of desiccation on stream epilithic algae. New Zealand Journal of Marine and Freshwater Research 35: 173–179. O’Sullivan, L. A., K. E. Fuller, E. M. Thomas, C. M. Turley, J. C. Fry & A. J. Weightman, 2004. Distribution and culturability of the uncultivated ‘AGG58 cluster’ of the Bacteroidetes phylum in aquatic environments. FEMS Microbiology Ecology 47: 359–370. Piccolo, A., 2001. The supramolecular structure of humic substances. Soil Science 166: 810–832. Quesada, A., J.-L. Mouget & W. F. Vincent, 1995. Growth of Antarctic cyanobacteria under ultraviolet radiation: UVA counteracts UVB inhibition. Journal of Phycology 31: 242–248. Hydrobiologia (2013) 719:43–58 Rees, G. N., G. O. Watson, D. S. Baldwin & A. M. Mitchell, 2006. Variability in sediment microbial communities in a semipermanent stream: impact of drought. Journal of the North American Benthological Society 25: 370–378. Ricart, M., H. Guasch, D. Barceló, R. Brix, M. H. Conceição, A. Geiszinger, M. J. López de Alda, J. C. López-Doval, I. Muñoz, C. Postigo, A. M. Romanı́, M. Villagrasa & S. Sabater, 2010. Primary and complex stressors in polluted Mediterranean rivers: Pesticide effects on biological communities. Journal of Hydrology 383: 52–61. Roberts, S., S. Sabater & J. Beardall, 2004. Benthic microalgal colonization in streams of differing riparian cover and light availability. Journal of Phycology 40: 1004–1012. Robson, B. J. & T. G. Matthews, 2004. Drought refuges affect algal recolonization in intermittent streams. River Research and Applications 20: 753–763. Robson, B. J., T. G. Matthews, P. R. Lind & N. A. Thomas, 2008. Pathways for algal recolonization in seasonallyflowing streams. Freshwater Biology 53: 2385–2401. Romanı́, A. M., 2010. Freshwater biofilms. In Dürr, S. & J. C. Thomason (eds), Biofouling. Wiley-Blackwell, Oxford: 137–153. Romanı́, A. M. & S. Sabater, 1997. Metabolism recovery of a stromatolitic biofilm after drought in a Mediterranean stream. Archiv für Hydrobiologie 140: 261–271. Romanı́, A. M. & S. Sabater, 1998. A stromatolitic cyanobacterial crust in a Mediterranean stream optimizes organic matter use. Aquatic Microbial Ecology 16: 131–141. Romanı́, A. M. & S. Sabater, 1999. Epilithic ectoenzyme activity in a nutrient-rich Mediterranean river. Aquatic Sciences 61: 122–132. Romanı́, A. M. & S. Sabater, 2000. Influence of algal biomass on extracellular enzyme activity in river biofilms. Microbial Ecology 41: 16–24. Romanı́, A. M. & S. Sabater, 2001. Structure and activity of rock and sand biofilms in a Mediterranean stream. Ecology 82: 3232–3245. Romanı́, A. M., H. Guasch, I. Muñoz, J. Ruana, E. Vilalta, T. Schwartz, F. Emtiazi & S. Sabater, 2004a. Biofilm structure and function and possible implications for riverine DOC dynamics. Microbial Ecology 47: 316–328. Romanı́, A. M., A. Giorgi, V. Acuña & S. Sabater, 2004b. The influence of substratum type and nutrient supply on biofilm organic matter utilization in streams. Limnology and Oceanography 49: 1713–1721. Romanı́, A. M., E. Vazquez & A. Butturini, 2006. Microbial activity and size fraction of dissolved organic carbon after drought in an intermittent stream: biogeochemical link across the stream-riparian interface. Microbial Ecology 52: 501–512. Rusch, A., M. Huettel, E. Reimers, G. L. Taghon & C. M. Fuller, 2003. Activity and distribution of bacterial populations in Middle Atlantic Bight shelf sands. FEMS Microbiology Ecology 44: 89–100. Sabater, S., 2009. The diatom cell and its taxonomical entity. Encyclopedia of Inland Waters 1: 149–156. Sabater, S., H. Guasch & A. M. Romanı́, 2000. Stromatolitic communities in Mediterranean streams: adaptations to a changing environment. Biodiversity and Conservation 9: 379–392. Sabater, S., S. Bernal, A. Butturini, E. Nin & F. Sabater, 2001. Wood and leaf debris input in a Mediterranean stream: the 57 influence of riparian vegetation. Archiv für Hydrobiologie 153: 91–102. Sabater, S., A. Elosegi, V. Acuña, A. Basaguren, I. Muñoz & J. Pozo, 2008. Effect of climate on the trophic structure of temperate forested streams. A comparison of Mediterranean and Atlantic streams. The Science of the Total Environment 390: 475–484. Sabater, S., J. Artigas, A. M. Romanı́, A. Gaudes, I. Muñoz & G. Urrea, 2011. Long-term moderate nutrient inputs enhance autotrophy in a forested Mediterranean stream. Freshwater Biology 56: 1266–1280. Sala, M. M., M. Karner & C. Marrasé, 2001. Measurement of ecoenzymatic activities as an indication of inorganic nutrient imbalance in microbial communities. Aquatic Microbial Ecology 23: 310–311. Salcher, M., J. Pernthaler & T. Posch, 2010. Spatiotemporal distribution and activity patterns of bacteria from three phylogenetic groups in an oligomesotrophic lake. Limnology and Oceanography 55: 846–856. Santmire, J. A. & L. G. Leff, 2007. The influence of stream sediment particle size on bacterial abundance and community composition. Aquatic Ecology 41: 153–160. Scherer, S., A. Ernst, T.-W. Chen & P. Böger, 1984. Rewetting of drought-resistant blue-green algae: time course of water uptake and reappearance of respiration, photosynthesis, and nitrogen fixation. Oecologia 62: 418–423. Scherer, S., T. W. Chen & P. Bäger, 1988. A new UV-A/B protecting pigment in the terrestrial cyanobacterium nostoc commune. Plant Physiology 88: 1055–1057. Simon, M., H.-P. Grossart, B. Schweitzer & H. Ploug, 2002. Microbial ecology of organic aggregates in aquatic ecosystems. Aquatic Microbial Ecology 28: 175–211. Sinsabaugh, R. L. & J. J. Follstad Shah, 2010. Integrating resource utilization and temperature in metabolic scaling of riverine bacterial production. Ecology 91: 1455–1465. Sinsabaugh, R. L., B. H. Hill & J. J. Follstad Shah, 2009. Ecoenzymatic stoichiometry of microbial organic nutrient acquisition in soil and sediment. Nature 462: 795–798. Stanley, E. H., S. G. Fisher & J. B. J. Jones, 2004. Effects of water loss on primary production: a landscape-scale model. Aquatic Sciences 66: 130–138. Steenwerth, K. L., L. E. Jackson, F. J. Calderón, M. R. Stromberg & K. M. Scow, 2003. Soil microbial community composition and land use history in cultivated and grassland ecosystems of coastal California. Soil Biology and Biochemistry 35: 489–500. Tamaki, H., S. Hanada, Y. Kamagata, K. Nakamura, N. Nomura, K. Nakano & M. Matsumura, 2003. Flavobacterium limicola sp. nov., a psychrophilic, organic-polymerdegrading bacterium isolated from freshwater sediments. International Journal of Systematic and Evolutionary Microbiology 53: 519–526. ter Braak, C. J. F. & P. F. M. Verdonschot, 1995. Canonical correspondence analysis and related multivariate methods in aquatic ecology. Aquatic Sciences 57: 253–287. Timoner, X., V. Acuña, D. von Schiller & S. Sabater, 2012. Functional responses of stream biofilms to flow cessation, desiccation and rewetting. Freshwater Biology 57: 1565–1578. Tornés, E. & S. Sabater, 2010. Variable discharge alters habitat suitability for benthic algae and cyanobacteria in a forested 123 58 Mediterranean stream. Marine and Freshwater Research 61: 441–450. Tzoraky, O., N. P. Nikolaidis, Y. Amaxidis & N. T. H. Skoulikidis, 2007. In-stream biogeochemical processes of a temporary river. Environmental Science and Technology 41: 1225–1231. Van Gestel, M., J. N. Ladd & M. Amato, 1992. Microbial biomass responses to seasonal change and imposed drying regimes at increasing depths of undisturbed topsoil profiles. Soil Biology and Biochemistry 24: 103–111. Vázquez, E., A. M. Romanı́, F. Sabater & A. Butturini, 2007. Effects of the dry–wet hydrological shift on dissolved organic carbon dynamics and fate across stream–riparian interface in a Mediterranean catchment. Ecosystems 10: 239–251. Vázquez, E., S. Amalfitano, S. Fazi & A. Butturini, 2011. Dissolved organic matter composition in a fragmented Mediterranean fluvial system under severe drought conditions. Biogeochemistry 102: 59–72. Volk, C. J., C. B. Volk & L. A. Kaplan, 1997. Chemical composition of biodegradable dissolved organic matter in streamwater. Limnology and Oceanography 42: 39–44. Williams, D. D., 2006. The Biology of Temporary Waters. Oxford University Press, Oxford. Wittenberg, L., 2002. Structural patterns in coarse gravel river beds: typology, survey and assessment of the roles of grain size and river regime. Geografiska Annaler: Series A, Physical Geography 84: 25–37. Wobus, A., C. Bleul, S. Maassen, C. Scheerer, M. Schuppler, E. Jacobs & I. Röske, 2003. Microbial diversity and functional characterization of sediments from reservoirs of 123 Hydrobiologia (2013) 719:43–58 different trophic state. FEMS Microbiology Ecology 46: 331–347. Wu, J. & P. C. Brookes, 2005. The proportional mineralization of microbial biomass and organic matter caused by airdrying and rewetting of a grassland soil. Soil Biology and Biochemistry 37: 507–515. Ylla, I., A. M. Romanı́ & S. Sabater, 2007. Differential effects of nutrients and light on the primary production of stream algae and mosses. Fundamental and Applied Limnology/ Archiv für Hydrobiologie 170: 1–10. Ylla, I., C. Borrego, A. M. Romanı́ & S. Sabater, 2009. Availability of glucose and light modulates the structure and function of a microbial biofilm. FEMS Microbiology Ecology 69: 27–42. Ylla, I., I. Sanpera-Calbet, E. Vázquez, A. M. Romanı́, I. Muñoz, A. Butturini & S. Sabater, 2010. Organic matter availability during pre and post-drought periods in a Mediterranean stream. Hydrobiologia 657: 217–232. Zeglin, L. H., C. Dahm, J. E. Barret, M. N. Gooseff, S. K. Fitpatrick & C. D. Takacs-Vesbach, 2011. Bacterial community structure along moisture gradients in the parafluvial sediments of two ephemeral desert streams. Microbial Ecology 61: 543–556. Zoppini, A. & J. Marxsen, 2011. Importance of extracellular enzymes for biogeochemical processes in temporary river sediments during fluctuating dry–wet conditions. In Shukla, G. & A. Varma (eds), Soil Enzymology, Soil Biology. Springer, Heidelberg: 103–117. Zoppini, A., S. Amalfitano, S. Fazi & A. Puddu, 2010. Dynamics of a benthic microbial community in a riverine environment subject to hydrological fluctuations (Mulgaria River, Italy). Hydrobiologia 657: 37–51.