RU2724875C1 - Method for biological indication of early climatic and other ecological changes in marine ecosystems - Google Patents

Abstract

FIELD: hydrobiology; physics.SUBSTANCE: invention relates to a method for biological indication of early climatic changes in marine ecosystems. Method for biological indication of early climatic changes in marine ecosystems consists in monitoring hydrobionts, namely, behind the estuarine population of Semibalanus balanoides barnacles, constantly living in the marginal habitats, wherein the marginal biotope is identified and their number, biomass and distribution area are recorded once every 6 months, as well as measuring parameters of medium - temperature and salinity; detecting changes by comparing with results of previous observations, determining trends of indicator biological parameters in extreme gradient of natural factors, thereafter, early climatic and other ecological changes of ecosystems with operability from 6 months to 1–3 years are determined in accordance with direction and rate of changes of the marginal population of the species.EFFECT: above described method enables to detect early climatic and other ecological changes in marine ecosystems.1 cl, 2 dwg, 1 tbl

Description

The invention relates to ecology and environmental protection, and in particular to a method for assessing the direction of change of ecosystems of marine waters.

The consequences of climate change in the Arctic Ocean are of global importance, but the timely detection of their long-term trends by known methods is problematic, it is very late.

A known method of biological monitoring of the state of ecosystems of the water area of Kozmin Bay using marine hydrobionts as test objects (RF patent for invention No. 2670208), cultivated on a water plantation, and / or hydrobionts living in natural settlements of the water area, with different intervals. For this, the scallop Mizuhopecten yessoensis, the gray sea urchin Strongylocentrotus intermedius, the black sea urchin Mesocentrotus nudus, or meroplankton are used as hydrobionts. After sampling the tissues of the cultivated scallop Mizuhopecten yessoensis, their histomorphological analysis is carried out and the content of lipofuscin in the cells of the tissue is determined, while the size of the lipofuscin granules should be from 1 to 3 microns, conglomerates not more than 12 microns, and the occupied area not more than 0.1% of histological section area. The sizes of the coastal scallop Mizuhopecten yessoensis cultivated on a plantation in the bay area or the coastal scallop Mizuhopecten yessoensis living in natural settlements are also determined, and the data obtained are compared with normative indices or compared with normative indices, which are formed on the basis of average indices for 3-10 years for individuals living in natural settlements. In addition, the mass and size of the gray sea urchins Strongylocentrotus intermedius or the black sea urchins Mesocentrotus nudus are determined or the quantitative composition of meroplankton is determined and compared with standard indicators, which are formed on the basis of average values for 3-10 years. With a change in the quantitative, dimensional and age and sex indicators of marine aquatic organisms as compared with standard indicators, they conclude that the sources of pollution affect the state of marine ecosystems and the ecological state of the water area of Kozmin Bay.

A known method of biological monitoring based on bioindication (RF patent for the invention No. 2357243). The method of biological monitoring based on bioindication involves the sampling of aquatic animals, establishing their abundance, biomass, species diversity, distribution boundaries and recording the functional parameters of the body, as well as the main hydrological and hydrochemical indicators, determining on their basis the spatial and temporal trends of indicator biological parameters in gradient of environmental factors. Biomonitoring is carried out continuously through multilevel bioindication, using several levels of organization of biological systems and measuring indicator parameters with different discreteness. At the same time, the results of operational bioindication on the physiological and behavioral reactions of the body in natural conditions characterize changes in the state of the environment in the range from 1 hour to 6 months, short-term bioindication - according to the parameters of populations of individual species - characterize the range from 0.5 years to 3 years, long-term bioindication on community level assess changes with an interval of 3 years or more. Assessment of environmental changes is carried out by comparing with background and reference trends of indicator parameters.

A disadvantage of the known biomonitoring methods is the limitedness of their action: the assessment of only anthropogenic environmental changes and / or the ability to track chronic changes in the aquatic environment only after a delay of 3-5 or more years, and the indicative nature of the results. Climate changes, especially the earlier ones, are not monitored by these methods.

Bioindication is considered a reliable tool for quickly obtaining information on environmentally significant environmental changes. The response of the climate bio-indicator species is the most rapid and noticeable, because this species is stronger than others, dependent on climate fluctuations.

The inventive method of biological indication of early climatic and other long-term changes in marine ecosystems, as well as known ones, involves observing (surveying, fixing) aquatic organisms living in natural settlements of the water area, establishing their abundance, biomass, boundaries (area) of distribution, determining trends based on them indicator biological parameters in the gradient of natural environmental factors.

The technical problem of the invention is the development of technology for early detection of trends in ecosystem changes under the influence of climate.

The technical result achieved by the implementation of the claimed invention is to identify early climatic and other environmentally significant changes in marine ecosystems.

The technical result is achieved by the fact that as bioindicators use hydrobionts, constantly living in the conditions of regional biotopes. The regional biotope is identified, where at a frequency of 1 time in 6 months, hydrobionts, mainly epibionts are taken, their abundance, biomass and distribution area are determined, as well as measurement of environmental parameters - temperature and salinity; identify changes by comparison with the results of previous measurements, determine trends in indicator biological parameters in the extreme gradient (ecocline) of natural factors of the regional biotope, determine early climatic or other environmental changes in the environment in accordance with the direction and rate of change in the regional population of the species. As hydrobionts, an estuarine population of barnacle barnacles Semibalanus balanoides, which lives in critical salinity zones, can be used.

The proposed technology provides for the use as bioindicators only hydrobionts, constantly living in the conditions of regional biotopes. The optimal biotope selection is the know-how of the authors.

Estimate populations of dominant sessile epibionts of the bottom fauna and flora are effective as climate bioindicators.

Ecocline is considered as a spatial gradual change in natural communities or a change in the abundance parameters of individual populations (animals and plants) adapted to the local habitat along the gradient of a particular environmental factor. Ecoton refers to the spatial change of communities and populations in a complex gradient of natural factors.

The authors first established that in extreme gradients of marginal biotopes, the pressure of environmental conditions reaches a maximum, making organisms much more sensitive to changes in environmental factors.

Thus, the claimed method is based on the fact that if the local population is in extreme conditions of the regional biotope, under strong pressure of several limiting factors, its response to environmental changes is many times stronger and faster than that of populations under optimal conditions. As a result, bioindication based on monitoring of local regional populations makes it possible to detect both long-term and short-term (from 6 months) consequences of environmental changes.

To indicate climatic changes, the main attention is paid to the population of the climate bio-indicator species, which reacts more strongly and faster than other aquatic organisms to changes in the conditions of both the water and air environments.

The action of this mechanism of bioindication of early climate changes is shown by the example of the regional population of barnacle barnacles Semibalanus balanoides living in the Kola Bay of the Barents Sea.

The sharper the gradients of the factors and the stronger the ecocline and ecotone, the greater the stress experienced by organisms and the fewer species can survive in conditions of strong gradients. Usually extremely tolerant littoral species, such as Semibalanus balanoides, are located in ecotones of regional biotopes in a very vulnerable position due to extremely strong pressure of environmental factors.

Therefore, under conditions of critical salinity of estuarine zones, the slightest changes in limiting factors immediately respond to the abundance parameters and distribution of organisms. For example, even a slight decrease in the average salinity by 1-2% o already matters and is immediately reflected in the change in the number of balyanus, up to their complete death in individual areas. On the littoral, under the conditions of a double “pressure” of environmental factors — reduced salinity of the water and drainage, even a slight, at first glance, increase in the time of exposure of the balanus in the air (by 20–40 min), which is safe for them on the usual marine littoral, also becomes critical .

Thus, in the gradients of the marginal littoral biotopes, the pressure of environmental conditions reaches a maximum, making organisms much more sensitive even to minor, for optimal conditions, changes in environmental factors, for example, temperature, salinity.

Sessile organisms — epibionts living on the surface of littoral soil, stones, which are least protected from the influence of external conditions and are exposed to direct atmospheric influences at low tide — are most effectively used as climate bioindicators. For the Barents and White Seas, such bioindicators are Semibalanus balanoides, barnacles, epibionts, which are clearly visible on the intertidal zone, living everywhere, including in zones of critical salinity.

Monitoring the populations of other littoral bottom organisms (mollusks, crustaceans, polychaete worms, local fish, algae) by one or two dominant factors in the ecocline of regional biotopes can also identify potential bioindicators of environmental environmental changes, including climate ones.

The proposed technical solution is feasible, which is confirmed by the following information and is illustrated using figures.

In FIG. Figure 1 shows the ecocline of the number of barnacle crayfish S. balanoides in the settlements of the middle (gray columns) and lower (black) horizons of the estuary littoral of the r. Tuloma has a salinity gradient from 2 (section 3) to 6% o (section 7, m. Spruce) on the surface at low tide.

In FIG. 2. Long-term changes in the abundance of S. balanoides balyanus and water salinity on the surface (edge) and in crustacean settlements (in streams) of the marginal biotope of the estuary littoral of Kuta Kola Bay are reflected.

On the example of a population of epibiont littoral crustaceans -balyanus S. balanoides estuary littoral p. Tuloma of the western (left) coast of Kuta Kola Bay, a method for detecting early climate changes using bioindication was tested. Long-term studies (2003-2018) were carried out on a large material: more than 420 measurements of salinity and 739 abundance over 87 surveys aimed at finding methods to detect early environmental changes in the marine environment, including those caused by global warming.

A comparative analysis of population changes by indicators of the abundance and area (boundaries) of crustacean clusters has established that both the specific narrow distribution of balyanus and their habitat only in the channels of littoral streams (runoff of littoral waters) and their degree distribution in the ecocline of the regional biotope are determined, first turn, a gradient of salinity of water close to critical (Fig. 1).

It was found that from 2007 to 2018. there was a steady decrease in the number of balianus, while a gradual increase in salinity in the littoral was observed (Fig. 2). It was established that the salinity of littoral waters increased due to a regular increase in evaporation during climate warming and, accordingly, gradual salinization of littoral soil during periods of drainage (during semi-daily tides). The number of balyanus fell significantly over several years, including due to the periodic increase in the duration of desalination in spring and summer with an increase in the flow of the river. Tulomas in some years of climatic fluctuations 2007-2018

In 2007-2008, there was a sharp decline in numbers up to the complete disappearance of crustaceans in the sections of the site closest to the river. According to the data obtained, this coincided with an anomalous increase in the power (volume and duration) of runoff r. Tuloma in the spring-summer period of 2007-2008 After that, the average number of balyanus remained at a reduced level for several years, experiencing slight fluctuations against the background of a general tendency to further decrease. A steady decline in the regional population became apparent after 2013 and especially noticeable after 2015, already without visible signs of recovery.

Thus, the influence of climate on the population of the bioindicator species was complex: an increase in heating and evaporation in the littoral on the one hand and an increase in the amplitude of fluctuations of the river flow and its thickness on the other.

A decrease in the number of S. balanoides after 2004 and an increase in the death of balyanuses (adults and spatha) on the estuary littoral from 2007 to 2018. they are quite adequate to the global warming trend and occur due to a significant change in the complex of environmental factors, anomalous for this regional population. In typical Murman marine littoral biotopes, a decrease in the number of balyanus was not observed (table). Although climatic changes are also taking place in marine biotopes of littoral and sublittoral zones, they are imperceptible or unreliable in the early stages, and will become apparent in the later stages of climate change.

Consequently, the marginal population of S. balanoides, located in conditions of critical salinity of water, can be considered a bioindicator of early climatic changes. A significant change in the number of balyanus was noticeable only in the marginal biotope of the estuary. Under conditions of normal salinity, marine populations of barnacles have not changed or have grown.

Therefore, early bioindication of climate change is possible and feasible only on the basis of monitoring the regional populations of littoral communities.

The dynamics of the population of barnacle cancers of S. balanoides under the conditions of the regional biotope indicates continued climate warming for the past 10 years. Moreover, according to bioindication, climate change is not uniform, but with fluctuations-jumps - stepwise, after each jump of 2-3 years there follows a period of "rollback" or stabilization at a new level, then again jumps, etc. These fluctuations in numbers confirm that if the trend of climate warming changes towards cooling, the regional population of the bioindicator species will respond accordingly, its area and number will begin to increase rapidly.

The response of the estuary marginal biotope balianus to climate change is reliably determined with an operativeness of 6 months to 1-3 years, which is unique in speed and, of course, much faster than reactions of both marine populations of the species and sublittoral bottom communities.

It is important to note that while under normal salinity the reaction of the population to small fluctuations in the limiting factors (temperature, salinity, drainage) is not noticeable for several years, then under the conditions of the estuary littoral and, especially, under conditions of critical salinity, crustaceans, on the verge of survival, respond to changes in factors much faster than in marine populations.

An analysis of the results showed that under the conditions of ecocline and ecotone of marginal biotopes, the body's dependence on environmental factors increases many times.

The proposed method provides the ability to identify early climatic and other environmental changes in marine ecosystems.

Claims (2)

1. A method for biological indication of early climatic changes in marine ecosystems, which includes observing hydrobionts living in natural settlements of the water area, establishing their abundance, biomass, distribution boundaries, determining, on their basis, trends in indicator biological parameters in the gradient of natural environmental factors, characterized in that as an bioindicator, use the estuarine population of barnacle barnacles Semibalanus balanoides, constantly living in the conditions of regional biotopes, while the regional biotope is identified, with a frequency of 1 time in 6 months they monitor hydrobionts living in the conditions of regional biotopes, determining their number, biomass and area distribution, as well as measurement of environmental parameters - temperature and salinity; identify changes by comparing with the results of previous observations, determine trends in indicator biological parameters in an extreme gradient of natural factors, determine early climatic and other ecological changes in ecosystems with a speed of 6 months to 1-3 years in accordance with the direction and rate of change of the regional population of the species. 2. The method according to p. 1, characterized in that the biological indication based on biomonitoring is carried out in areas of critical salinity.

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