4urn:lsid:arphahub.com:pub:27D7DBB2-BDE1-5A1F-B26F-1372106F69DBBioRiskBR1313-26441313-2652Pensoft Publishers10.3897/biorisk.14.3031930319Research ArticlePlantaeBiodiversity & ConservationBiogeographyData analysis & ModellingEcology & Environmental sciencesAfricaEuropeWorldImpact of hydromorphological pressures on the macrophytes bioindicators of the ecological water quality in Mediterranean riversAbdellahMaissourabdellah.maissour@usmba.ac.mahttps://orcid.org/0000-0001-5297-93861SaadBenamarsaad.benamar@usmba.ac.ma1Laboratoire des Sciences Environnementales Végétales et Urbaines (LSEVU), Ecole Normale Supérieure de Fès, Université Sidi Mohamed Ben Abdellah, B.P. 5206 Bensouda, Fès, MoroccoUniversité Sidi Mohamed Ben AbdellahFezMorocco
201909052019141141A0682E0-5D0F-5700-A8B5-42F7F0B5E62534849660410201810042019Maissour Abdellah, Benamar SaadThis is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
One of the important tools to evaluate the ecological quality of surface water is the Macrophytes indices based on the bioindication capacity of aquatic plants. In Mediterranean rivers (France, Spain, and Portugal), the development of some macrophytes indices like l’Indice Biologique Macrophytes Rivières (IBMR), the biological metric score (BMS), as well as the Fluvial Macrophyte Index (IMF) are founded on the determination of the indicator values of the floristic reference lists.
The aim of this study was to test the impact of the eco-Mediterranean differences (from one country to another) on the indicator taxa by comparing the indicator values of the Euro‐ Mediterranean macrophyte indices. With this in mind, we explore the possibility of the introduction of the Euro‐Mediterranean macrophytes-based indices in Morocco (i.e. the hydrological basin of Sebou (HBS)) as a part of a preliminary attempt to develop the first Afro-Mediterranean macrophyte index.
We confirm that the ecological amplitude and species optima vary between Mediterranean ecoregions, and indicator taxa differ between countries: There are medium to small correlations between Mediterranean indices: IBMR/BMS (p = 0.000, R2 = 0.57), IMF/BMS (p = 0.000, R2 = 0.34), and IBMR/IMF (p = 0.000, R2 = 0.30). Five species exhibit major differences in indicator values: Zannichelliapalustris and Potamogetonpectinatus have more eutrophic indicator values in France (IBMR) than in Spain (IMF). Potamogetonnodosus, Amblystegiumriparium and Lycopuseuropaeus have broader ecological amplitudes in Portugal (BMS) than in France (IBMR) and in Spain (IMF), where it is restricted to eutrophic conditions. Furthermore, the three indicator systems include different indicator-taxon numbers.
The comparison of the HBS elaborated list with the Euro‐Mediterranean indices revealed the low level of common taxa approximately 6.76% of all indicator species used in the French index (IBMR), 10.48% in the Portuguese index (IMF) and 12.38% in the Spanish index (BMS).
These results show the inadequacy of the trophic indices approach with the HBS conditions and thus the need for the development of an index based on biotic indices approach.
Ecological water qualityMacrophytesreference listbioindicationhydromorphologyMediterranean riversCitation
Abdellah M, Saad B (2019) Impact of hydromorphological pressures on the macrophytes bioindicators of the ecological water quality in Mediterranean rivers. BioRisk 14: 1–14. https://doi.org/10.3897/biorisk.14.30319
Introduction
Due to their high sensibility to different environmental stresses and their ability to assess the dynamic and the cumulative effects of different stressing factors, macrophytes species are considered good bioindicators. This bioindication power of macrophytes has generated a proliferation in the number of macrophyte-based indices in the last decades.
At the present time, the approaches for estimating macrophyte communities’ quality in the Mediterranean rivers are:
• The approach based on the assumption that environments that have not been impacted have a greater diversity of species than degraded environments (community structure approaches): Indice di Biodiversita` Riparia (IBR) (Maggioni et al. 2009) in Italy is based on biodiversity of macrophytes on the banks. (Patrick 1977) proved that assemblages with similar diversity scores could represent streams with significantly different chemical conditions.
• The Biotic indices approach based on the assumption that biological assemblages in impaired sites should be different from those in reference sites:
▪ The Iberian multimetric plant index (IMPI) (Ferreira et al. 2005), in the Iberian Peninsula (Portugal, Spain).
▪ The Riparian Vegetation index (RVI) (Aguiar et al. 2009) in Portugal.
▪ River Macrophyte Index (RMI) (Kuhar et al. 2011) in Slovenia, based on the relative abundance of sensitive and/or tolerant taxa.
• The approach based on indicator values calculated for an elevated number of aquatic species, according to the species’ relative sensitivity and tolerance to nutrients and/or to other abiotic stress factors. The Indices designed to respond to nutrient enrichment using indicator species in Mediterranean rivers are:
◦ The Indice Biologique Macrophytique en Rivières (IBMR): developed in France by (Haury et al. 2006) for assessing water trophy and organic pollution and calculated using the following formula:
where Csi is the specific rate of trophic level– ranged from 0 (heavy organic pollution and heterotrophic taxa) to 20 (oligotrophy); Ei represents the coefficient of ecological amplitude: Coefficient 1, representing wide amplitude, covered three classes of trophy, and coefficient 3, representing a very limited amplitude, was restricted to just one class; Ki is the scale of cover, going from 1 to 5 (1: <0,1%; 2: 0,1 – <1%; 3: 1– <10%; 4: 10 – <50%; 5: ≥50%).
◦ The biological metric scores (BMS): developed by (Dodkins et al. 2012) in Portugal. This index is the mean of the species scores that occur at that site, weighted by their cover, i.e. the Weighted Averaging (WA) equation (Braak and Looman 1986):
where S = site score, n = number of species; Ci = cover scale value of species i; and Qi = score of species i. The cover scale values used to weight the mean were: 0 (for 0% macrophyte cover relative to the channel area), 1 (≤1% cover), 2 (≤5% cover), 5 (≤33% cover) and 6 (>33 cover).
◦ The index of macrophytes (IM), the Macroscopic Aquatic Vegetation Index (IVAM) and The Fluvial Macrophyte Index (IMF) (Alcaraz et al. 2006; Flor-Arnau et al. 2015; Suárez et al. 2005) in Spain. The Fluvial Macrophyte Index (IMF) is calculated using the following formula:
where Ki is the coating of the taxa at the station -range: 1-5; 1 (<0.1%), 2 (0.1–1%), 3 (1–10%), 4 (10–50%), 5 (> 50%); Csi is the sensitivity value for eutrophy (range: 1–20); Ei is the value of stenoicity or ecological amplitude (range: 1–3). The IMF score is obtained from the formula of Zelinka and Marvan (1961).
Taking into consideration that the development of macrophytes assemblages strongly depends on a variety of abiotic and biotic factors and it is assumed that the most important of them are nutrient concentrations (Dodkins et al. 2012; Robach et al. 1996; Schneider et al.2000; Szoszkiewicz et al. 2006; Thiebaut et al. 2002; Whitton 1975), and hydromorphological characteristics, such as altitude, flow velocity, water depth, width of river bed and type of substrate (Baláži and Hrivnák 2017), the overall purpose of this paper is to investigate the influence of localized hydromorphological differentiation for the bioindication of macrophytes in Mediterranean countries. In particular, we focus on the following question: Is there evidence of a role of hydromorphological differentiation in the diversity of macrophyte taxa included in Mediterranean indices? Is there any evidence for the impact of ecoregion differentiation on the macrophytes indicator values? In other words, are the macrophytes more impacted by trophic status or by the hydromorphological characteristics of each Mediterranean country? Is there any possibility to adopt and/or adapt any Euro-Mediterranean macrophytes-based indices in Morocco (HBS)?
Methods
All currently used and published Mediterranean macrophyte indices based on species indicator values for assessment of river trophic status are included in this study. We didn’t take into consideration indices with low taxonomic rank resolution (family and order): Macroscopic Aquatic Vegetation Index (IVAM) and the index of macrophytes (IM). Three macrophyte indices meet the above-indicated criteria: The Fluvial Macrophyte Index (IMF), the Biological metric scores (S), and l’Indice Biologique Macrophytes Rivières (IBMR).
Comparison of species indicator values between different Mediterranean indices was performed using correlation analysis.
An extensive field survey of macrophytes communities (aquatic and riparian species) in HBS and its tributaries (39 stations) has been carried out. Identification of the macrophytes was taken using field identification guides (Ahayoun et al. 2007; Coudreuse et al. 2005; Fennane et al. 1999; Fennane et al. 2007; Valdés 2002).
In order to ensure comparability of species, taxa names were screened for synonyms and harmonized if necessary.
ResultsMediterranean indices comparison
The most striking results to emerge from Mediterranean indices comparison are:
IBMR compared to IMF
A total of 68 species are included in both IBMR and IMF. Half of these species have an IMF value between 16–18 (Figure 3). The indicator values are significantly correlated (p = 0.000, R2 = 0.30) (Figure 2). Two species differ from the regression curve. In the two cases the IBMR value is lower than the IMF (Zannichelliapalustris, Potamogetonpectinatus).
A total of 158 taxa have only an IBMR, but not an IMF indicator value, while 56 taxa have only IMF indicator value but not an IBMR.
IBMR compared to BMS
A total of 47 species are included in both IBMR and BMS. The indicator values are significantly correlated (p = 0.000, R2 = 0.57). Two species differ from the regression curve. In the two cases the IBMR value is lower than the IMF (Amblystegiumriparium, Potamogetonnodosus).
A total of 179 taxa have only an IBMR, but not a BMS indicator value, while 58 taxa have only an IMF indicator value but not an IBMR.
IMF compared to BMS
A total of 35 species are included in both IMF and BMS. The indicator values are significantly correlated (p= 0.000, R2=0.34). One species differs from the regression curve. In this case the IMF value is lower than the BMS (Lycopuseuropaeus).
A total of 89 taxa have only an IMF, but not BMS indicator values, while 70 taxa have only BMS indicator values but not IBMR.
HBS macrophytes compared to European trophic indices
Our field work and analysis revealed that a limited number (23 indicator species) of macrophytes recorded in HBS are utilized as bioindicators in biological monitoring for the ecological status assessment in rivers in Euro‐Mediterranean countries (Table 1). Fourteen species are used in IBMR, thirteen species in BMS and IMF. This limited number of indicator species represents only 6.76% of all indicator species used in the French index (IBMR), 10.48% in the Portuguese index (IMF) and 12.38% in the Spanish index (BMS).
The list of aquatic taxa of HBS that are included in IBMR, BMS, IMF.
Species
IBMR
BMS
IMF
Csi
Ei
Qi
Csi
Ei
Agrostisstolonifera
10
1
12
2
Arundodonax
1
Berulaerecta
14
2
Elodeacanadensis
10
2
1
Epilobiumhirsutum
2
4
1
Equisetumramosissimum
18
3
Helosciadiumnodiflorum
10
1
3
4
1
Hygrohypnumluridum
19
3
Lemnagibba
5
3
2
8
2
Ludwigiapalustris
5
Menthaaquatica
12
1
3
12
2
Menthalongifolia
18
3
Menthapulegium
4
Nasturtiumofficinale
11
1
2
8
2
Phragmitesaustralis
9
2
1
Potamogetonnodosus
4
3
3
Potamogetonpectinatus
2
2
8
3
Ranunculusbulbosus
4
Rumexconglomeratus
8
2
Scrophulariaauriculata
4
1
Typhaangustifolia
6
2
Veronicabeccabunga
10
1
3
12
3
Zannichelliapalustris
5
1
16
3
If we extend our analysis to other European indices i.e.:
• The British index: The Mean Trophic Rank (MTR), there are only ten species of HBS that have MTR indicator value: Berulaerecta, Elodeacanadensis, Helosciadiumnodiflorum, Hygrohypnumluridum, Lemnagibba, Nasturtiumofficinale, Phragmitesaustralis, Potamogetonpectinatus, Typhaangustifolia, Zannichelliapalustris.
• The German index: Trophic Index of Macrophytes (TIM), there are only eight species of HBS that have TIM indicator value: Berulaerecta, Elodeacanadensis, Menthaaquatica, Nasturtiumofficinale, Potamogetonnodosus, Potamogetonpectinatus, Veronicabeccabunga, Zannichelliapalustris.
All these species are included in the Euro Mediterranean indices, especially in the French index.
One of the most common species used in European countries’ indices (MTR, TIM, IBMR, IMF and BMS) and taking place in HBS is Nasturtiumofficinale.
Based on IBMR index we have in HBS some species representing wide amplitude (Ei = 1): Menthaaquatica, Nasturtiumofficinale, Agrostisstolonifera, Helosciadiumnodiflorum, Veronicabeccabunga, Zannichelliapalustris. And some species representing a very limited amplitude (Ei = 3): Hygrohypnumluridum, Lemnagibba, Potamogetonnodosus. Furthermore, some species indicating hypertrophic conditions (e.g. Potamogetonpectinatus, Potamogetonnodosus, Csi = 2–4) and others indicating oligotrophic conditions (e.g. Hygrohypnumluridum, Csi = 19).
Based on BMS index, species associated with high conductivity and nutrient enrichment (Qi = 1) are: Elodeacanadensis, Phragmitesaustralis, Arundodonax.
IMF index reveals some species representing wide amplitude (Ei = 1): Epilobiumhirsutum, Helosciadiumnodiflorum, Scrophulariaauriculata. Species representing a very limited amplitude (Ei = 3): Equisetumramosissimum, Menthalongifolia, Veronicabeccabunga, Potamogetonpectinatus, Zannichelliapalustris. Some species indicating hypertrophic conditions (e.g. Epilobiumhirsutum, Helosciadiumnodiflorum, Scrophulariaauriculata, Csi = 4) and others indicating oligotrophic conditions (e.g. Equisetumramosissimum, Menthalongifolia, Csi = 18).
Discussion
The most obvious difference between the three indicator systems is the number of included indicator taxa: IBMR (226), IMF (124), BMS (105), and TIM (49).
The IMF and the BMS have the fewest species in common (35 common taxa compared to 47 between IBMR and BMS and 68 between IBMR and IMF).
The allocation of the trophic values was based on empirical studies (correlation between species occurrence and impact parameters), literature data and expert opinion in TIM and IBMR. In BMS and IMF, the trophic values were determined only by empirical studies.
IBMR and BMS are moderately correlated (R2=0.57). The worst correlation occurs between IBMR and IMF (R2=0.30).
In France (IBMR), Zannichelliapalustris and Potamogetonpectinatus have more eutrophic indicator values than in Spain (IMF) (Figure 2). Zannichelliapalustris is commonly associated with nutrient-rich conditions (Vukov et al. 2018) as well as Potamogetonpectinatus. For instance, in Germany (Trophic Index of Macrophytes (TIM) (Schneider and Melzer 2003)) and Poland (Macrophyte Index for Rivers (MIR)) Zannichelliapalustris and Potamogetonpectinatus are used as indicator of eutrophic conditions. However, in the UK (Mean Trophic Rank (MTR) (Dawson et al. 1999)), those species are seen to be tolerant of eutrophication, or cosmopolitan in their requirements (Table 2).
Zannichelliapalustris and Potamogetonpectinatus indicator values in MTR, TIM, and MIR.
Zannichelliapalustris
Potamogetonpectinatus
Mean Trophic Rank (MTR) UK
STR = 2 tolerant of eutrophication or are cosmopolitan in their requirements.
STR = 1 tolerant of eutrophication or are cosmopolitan in their requirements.
Trophic Index of Macrophytes (TIM) Germany
IV = 2.93 meso-eutrophic (m-eu) – eutrophic (eu)
IV = 2.88 meso-eutrophic (m-eu) – eutrophic (eu)
Macrophyte Index for Rivers (MIR) Poland
L = 2 eutrophic
L=1 eutrophic
Potamogetonnodosus, Amblystegiumriparium and Lycopuseuropaeus have more oligotrophic indicator values in Portugal (BMS) than in France (IBMR) and in Spain (IMF) (Figure 2).
In Poland (MIR), Potamogetonnodosus tends to be used to refer to eutrophic conditions. In Germany (TIM), it is used as an indicator of eutrophic to polytrophic conditions, which is consistent with the eutrophic BMS, IBMR and IMF indicator values. It is therefore likely that Potamogetonnodosus has a broader ecological amplitude. For instance, in Zambia (The Zambian Macrophyte Trophic Ranking scheme (ZMTR) (Kennedy et al. 2016)), this species is considered as ubiquitous species, occurring across from oligotrophic to eutrophic conditions (Table 3).
Amblystegiumriparium is described as tolerant of eutrophication or cosmopolitan in its requirements. So, it is therefore likely that this species has a broader ecological amplitude.
The apparent weak and moderate correlation and the difference of the included taxa and their indicator values from one index to another can be attributed to the hydromorphological characteristics of the Mediterranean rivers.
331 species are included in the Euro Mediterranean indices (IBMR, BMS and IMF) belonging to 98 families, 66 orders and 24 classes. The most diversified families are: Potamogetonaceae, Cyperaceae, Ranunculaceae, Amblystegiaceae, Typhaceae, Plantaginaceae, Characeae, Poaceae, Hydrocharitaceae, Apiaceae, Juncaceae (Figure 1).The most used genera are: Potamogeton (19 species), Ranunculus (19), Sparganium (9), Fissidens (8), Juncus (8), Carex (7), Callitriche (7), Chara (6), Equisetum (5), Montia (5) and Najas(5). These indices include some species of Chromista, Bacteria and Fungi (Table 4).
AC772133-B6D1-5240-B726-64F3452FAA4F
A families B classes, and C orders of macrophytes species included in the Mediterranean trophic indices: IBMR, IMF, and BMS.
https://binary.pensoft.net/fig/299940
Potamogetonnodosus and Amblystegiumriparium indicator values in TIM, ZMTR, MTR, and MIR.
Potamogetonnodosus
Amblystegiumriparium
Trophic Index of Macrophytes (TIM) Germany
IV=3.1 eutrophic (eu) – eu-polytrophic (eu-p)
The Zambian Macrophyte Trophic Ranking scheme (ZMTR) Zambia
ZTRSsp=(3 U) ubiquitous species, occurring across trophic categories from oligotrophic to eutrophic
Mean Trophic Rank (MTR) UK
STR = 1 tolerant of eutrophication or are cosmopolitan in their requirements
Macrophyte Index for Rivers (MIR) Poland
L = 3 eutrophic
List of Chromista, Bacteria and Fungi taxa used in Euro‐Mediterranean indices.
kingdom
species
IMF
IBMR
Bacteria
Nostoc
+
+
Oscillatoria
+
+
Phormidium
+
+
Sphaerotilus
+
Chromista
Cymbella
+
Leptomitus
+
Melosira
+
+
Tribonema
+
+
Vaucheria
+
+
Fungi
Collema dichotomum
+
Dermatocarpon luridum
+
The comparison of the HBS elaborated list with the Euro-Mediterranean indices revealed the low level of similarity between HBS community species and the floristic reference of the French index (IBMR), the Portuguese index (IMF) and the Spanish index (BMS).
Furthermore, there is a limited number of HBS aquatic species (31 species), which is in agreement with previous research (Benamar and Maissour 2014).
The high level of aquatic species in France and the low-level of aquatic species in HBS compared to the Euro-Mediterranean countries can be ascribed to the climate transition from thetemperate climate of central Europe to the arid climate of northern Africa (Giorgi et al. 2008). These Afro-Mediterranean conditions deeply affect stream flows (mixture of perennial and intermittent rivers) and the occurrence of aquatic species.
These results demonstrate the inadequacy of the trophic indices approach especially with the HBS conditions and in general in the Afro-Mediterranean region, and thus the need for the development of an index based on biotic indices approach taking into consideration also the riparian species.
The Biotic indices approach, which is originally developed by Karr and Dudley (1981), is a widely used method for evaluating anthropogenic pressures on aquatic and wetland ecosystems: Floristic Quality Assessment Index (FQAI) (Lopez and Siobhan Fennessy 2002), Integrity Biotic Index (IBI) (Miller et al. 2006), Iberian Multi metric Plant Index (IMPI) (Ferreira et al. 2005), Index of Plant Community Integrity (IPCI) (DeKeyser et al. 2003), Index of biotic integrity in Itanhaém (MIBI-ITA) (Umetsu et al. 2018), Plant Index of Biotic Integrity (PIBI) (Simon et al. 2001), Plant-based index of biotic integrity (PIBI) (PIBI(M)) (Moges et al.2016), Riparian Forest Quality index (QBR) (Munné et al. 2003), Riparian Quality Index (RQI) (Del Tanago et al. 2006; González del Tánago and García de Jalón 2006), Vegetation Index of Biotic Integrity (VIBI) (Mack 2007), and Vegetation-based index of biotic integrity (VIBI(Y)) (Yang et al. 2018).
3A23E475-AE0E-5FD0-B243-F13F7CFD924D
Polynomial regression of AIBMR and IMFBIBMR and BMSCIMF and BMS.
https://binary.pensoft.net/fig/299941
Among the potential characteristics of the aquatic vegetation (candidate metrics) that can be responsive to disturbance in HBS are: diversity, species habitat, life cycle, life form, nutritional resources, riparian structure, and species tolerance (Table 5).
Future work will involve the selection of the reference sites. This is because the reference sites provide the baseline information to detect the deviation of a metric from a natural or least-disturbed condition. And the selection of suitable metrics in our context. So, we need to evaluate the ability of every potential candidate metric in terms of its ability to distinguish reference (undisturbed or least-disturbed) from impaired (moderately or heavily disturbed) sites. Only the metrics showing significant difference between reference and impaired sites will be selected as the IBI-HBS metrics (Yang et al. 2018). The next step is to score the selected core metrics.
D01C8E2A-10E9-5881-97F3-CDB4D01235F4
boxplots: indicator values of species that are included in A (IBMR) and (IMF) B (IMF) and (BMS) C (IMF) and (BMS).
https://binary.pensoft.net/fig/299942
Potential candidate and core metrics in IBI- HBS.
Candidate metrics
Expected response to decreasing quality
River and wetland indices
Diversity
Species richness
Decrease
FQAI, PIBI, IPCI, MIBI-ITA
Species habitat
% Endemic species
Decrease
FQAI
% Native species
Increase
PIBI(M)
% Exotic species
Increase
PIBI(M)
Life cycle
% Annual species
Decrease
IMPI, IBI, VIBI,
% Perennial species
Increase
VIBI, PIBI, IPCI, VIBI(Y)
Life form
% Terrestrial species
% Hygrophyte species
RQI, PIBI
% Helophyte (emergent species)+ hydrophyte species (floating-leaved, free-floating, and submerged species)
Decrease
IMPI, VIBI, PIBI; MIBI-ITA
Nutritional resources
% Ruderal species
Increase
IMPI
% Nitrophyllous species
Increase
IMPI, RQI
Riparian structure
% Woody species richness (trees, shrubs, woody climbers)
Variable
IMPI, IBI, RQI, PIBI(M)
Species tolerance
Tolerant species richness
Increase
PIBI(M), VIBI(Y)
Sensitive species richness
Decrease
PIBI(M)
Conclusion
We have confirmed that the ecological amplitude and species optima vary between Mediterranean ecoregions, and that indicator taxa differ between countries.
It was found that the trophic indices of the Euro Mediterranean rivers can’t be applied easily to the Afro- Mediterranean rivers, particularly in Morocco (HBS), and we don’t have a good opportunity to enrich the list of indicative species due to the limited number of species recognized as bioindicators (23 species) and the limited number of aquatic species. So, it seems more appropriate to develop an index based on a biotic-integrity approach.
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Checklist of hydrological basin of Sebou macrophytes
occurences
https://binary.pensoft.net/file/299946This dataset is made available under the Open Database License (http://opendatacommons.org/licenses/odbl/1.0/). The Open Database License (ODbL) is a license agreement intended to allow users to freely share, modify, and use this Dataset while maintaining this same freedom for others, provided that the original source and author(s) are credited.Maissour Abdellah, Benamar Saad