Rio Tinto (Spain)

From MicrobeWiki, the student-edited microbiology resource

Introduction

Red waters of the Rio Tinto!


The Rio Tinto is a river in Southwestern Spain. It is a total of 100km long and flows from the city of Pena de Hierro out to the Atlantic Ocean in Huela. The waters of the Rio Tinto flow red due to a high concentration of ferric iron. The river is known as an extreme environment due to its low pH and high concentrations of heavy metals. The region has been an important copper mining area for the last 5000 years. It was originally thought that the low pH was caused by the copper mining, but it was later discovered that the low pH numbers are a result of the microbial activity and not of the system itself. The microbial eukaryotic communities show a stronger correlation with the concentration of heavy metals then with the pH of the water. What makes this acidic water system so unique is the fact that it’s primary contributor of biomass comes from eukaryotic micro organisms. It is estimated that up to 65% of total biomass within the system comes from these eukaryotic communities. The location of the primary biomass occurs on the river bend where dense compact biofilms from. These biofilms are primarily composed of fungi and algae. This is unique because most acidic waters with high metal concentrations are toxic to eukaryotes and limit both growth and biodiversity.

Physical environment

The Rio Tinto is known for its extreme environmental conditions of low pH and high concentrations of heavy metals. On average the pH of the water is around 2, but may very threw out the water system. Some areas measured as low as a 1.1 pH while other areas have recorded pH levels as high as 3. By general observation it has been noticed that the pH tends to be lower in beginning of the river and higher as the river nears the mouth. There are three primary heavy metals found in the water column, they are iron, copper, and zinc. Their averages threw out the year can range from 0.4g/L-20.3g/L for Iron, 0.02g/L-0.7g/L for copper, and 0.02g/L-0.56g/L for zinc. The concentrations of heavy metals within the water column have been found to vary seasonally. In the summer months of June threw September the heavy metal concentrations seem to be the highest. It is thought that this occurs due to that time of year being the dry season and having warmer temperatures. This results in lower water levels due to less rain and increased evaporation. These two conditions concentrate the heavy metals within the water system since less water is entering and more is leaving before ever reaching the mouth at the Atlantic. The average water temperatures range from 25*C in the summer to 15*C in the winter. As with most aquatic ecosystems the dissolved oxygen levels also very seasonally with the winter months containing higher concentrations of dissolved oxygen when compared to the warmer summer months.

Biological interactions

The most important biological interaction within the Rio Tinto is the rise in pH due to the oxidation of sulfur by acidic chemolithotrophic organisms. This effects everything within the aquatic ecosystem. Its so extreme that the average microbe cant even sustain life there. Everything within the ecosystem seems to revolve around the Iron and Sulfur cycles within the system. Iron oxidizing prokaryotes and iron reducers are capable of functioning in both anaerobic and aerobic conditions. The Ferric Iron produced is a limiting factor placed upon the Sulfur cycle. Below is a diagram to better show how Iron and Sulfur cycles are tied together, along with how the microbial populations work together to complete the cycles.

Biological interactions.jpg

Microbial processes

The microbial processes that define this environment are the oxidation of iron and sulfur. Sulfides are the main substrate of choice for the acidic chemolithotrophic organisms present in the Rio Tinto. Sulfides first undergo oxidation threw the polysulfide mechanism which will then produce elemental sulfur. At this state the microbes are able to further oxidize the sulfur into sulfuric acid. This is where the waters high pH levels stems from. The equations below can better help to show what is truly going on.

1) Fe3+ + 3H2O ⇔ Fe(OH)3 + 3H+

2) 8MS + 8Fe3+ + 8H+ → 8M2+ + 4H2Sn + 8Fe2+

3) 4H2Sn + 8Fe3+ → S08 + 8Fe2+ + 8H+

4) S08 + 12O2 + 8H2O → 8SO2−4 + 16H+

The remaining insoluble elements such as pyrite, tungstenite and molybdenite may disolve into the water column(oxidise) only by means of the thiosulfate mechanism which needs ferric iron. Example shown below.

5) FeS2 + 6Fe3+ + 3H2O → 7Fe2+ + S2O2−3 + 6H+

6) S2O2−3 + 8Fe3+ + 5H2O → 2SO2−4 + 8Fe2+ + 10H+

Key Microorganisms

Chemolithotrophs

These types of microbes oxidize inorganic compounds to obtain energy. Chemolithotrophs in the Rio Tinto are known as extremophiles as they are able to not only survive but also thrive in conditions that would normally kill or harm other microbes. To survive in the Rio Tinto these chemolithotrophs would need adaptations that would allow them to deal with the extreme pH levels along with the strong concentrations of heavy metals.

Photosynthetic Primary Producers

These microbes are able to produce their own food by means of extracting energy from sunlight. With this energy they are then able to fix carbon and perform other required tasks for survival. The most important Photosynthetic Primary Producers in the Rio Tinto is Acidophilic Algae. These microbes also require special adaptations to withstand low pH and strong concentrations of heavy metals.

Consumers

The primary consumers within the Rio Tinto are Eukaryotic Heterotrophic Protists. This means that they are organisms with a cell nuclease(eukaryote), and use organic carbon for growth since they are not able to produce their own food(Heterotroph).

Decomposers

These microbes are heterotrophic and rely on dead organisms to obtain carbon and other nutrients to sustain themselves. In the Rio Tinto ecosystem most decomposers found are either fungi or yeasts.

Examples of organisms within the group

Chemolithotrophs

Sulfur Oxidizing

The primary microbe found in the Rio Tinto that oxidizes sulfur is classified as At. ferroxidans. There were also 3 other microbes found although they are not considered significant in numbers. Some others were in the family of Acidithiobacillus genus and At. thiooxidans.

Iron Oxidizing

There have been many Iron oxidizing microbes found within the Rio Tinto. The two most important iron oxidizing microbes have been determined using specific fluorescent probes. The results showed that L.ferrooxidans and At. ferrooxidans are the most important. Other microbes were found and identified as Leptospirillum ferrooxidans, Acidithiobacillus ferrooxidans, and Ferroplasma spp.

Photosynthetic Primary Producers

As stated previously acidophilic algae accounts for 65% of biomass within the Rio Tinto ecosystem. The organisms identified were Bacillariophyceae (Diatoms), Chlorophyta (Chlamydomonas, Klebsormidium and Zignema), Euglenozoa (Euglena), and Rhodophyta (Galdieria)

Consumers

The major group of consumers within the Rio Tinto are Eukaryotic Hetertrophic protists. Some examples of these organisms are amoebae of the class Lobosea(phylum Rhizopoda), flagellates, some individuals from the class of Heliozoa (phylum Actinopoda) and ciliates(phylum Ciliophora) which are mainly associated with biofilms.

Decomposers

There are two primary types of decomposeres within the Rio Tinto, they are Fungi and Yeast. The most important acidic fungi group found belonged to the Dematiaceous group. This also included members of Bahusakala, Heteroconium, Phoma and Scytalidium genus. So far studies have also showed sixteen different forms of Penicillium spp. There have also been seven different genras of yeast found within the aquatic system, they are Candida, Cryptococcus, Holtermannia, Leucosporidium, Tremella, Rhodotorula and Hansenula.

Current Research

1. Photoreduction fuels biogeochemical cycling of iron in Spain's acid rivers- The purpose of this research was to analyze the photoreduction properties of Fe(III) for the Rio Tinto ecosystem. This will allow a better understanding of if this process is capable of supplying enough Fe(II) to be oxidized by bacteria, thus releasing enough free energy to support biological processes on mars. The conclusion is that this process could possibly play an important part on mars or other planetary systems.

References

[Sample reference] Takai, K., Sugai, A., Itoh, T., and Horikoshi, K. "Palaeococcus ferrophilus gen. nov., sp. nov., a barophilic, hyperthermophilic archaeon from a deep-sea hydrothermal vent chimney". International Journal of Systematic and Evolutionary Microbiology. 2000. Volume 50. p. 489-500.

Edited by student of Angela Kent at the University of Illinois at Urbana-Champaign.