Fungal impact on archaeological materials collected at Byers Peninsula Livingston Island, South Shetland Islands, Antarctica

MENEZES, GRACIÉLE C.A. DE; PORTO, BÁRBARA A.; RADICCHI, GERUSA A.; SOARES, FERNANDA C.; ZARANKIN, ANDRÉS; ROSA, LUIZ H.

doi:10.1590/0001-3765202220210218

Abstract

We identified cultivable fungi present on the surface of five archaeological sealers’ artifacts from the beginning of the 19^th century collected on Livingston Island, Antarctica. Twenty fungal isolates were recovered and identified using biology molecular methods as taxa of Antarctomyces, Linnemannia, Penicillium, Mortierella, Talaromyces, and Trichoderma. Penicillium was dominant on artifacts stored at 10 and 25 °C. In contrast, Antarctomyces, Linnemania, Mortierella, and Trichoderma occurred only on artifacts stored between 8 °C and 10 °C. Our results showed that the Antarctic artifacts harboured cosmopolitan mesophilic, cold-tolerant, and endemic psychrophilic fungal taxa. The mesophilic fungi might have contaminated the artifacts in situ, during sampling, transport, and/or storage in the laboratory collection or represent dormant but viable form capable to grow on the objects. However, the detection of cold-tolerant and endemic fungi shows that these fungi, when stored between 8 ° and 10 °C, continue growing on the objects, which may supply them with organic nutrients; this may accelerate degradation of artifacts in the collection. Preventive steps should be adopted to avoid further microbial contamination. Sterilised microbiological conditions can be followed during fieldwork and transportation to Brazil. The preventive protocol may represent a better alternative to avoid artifact microbial proliferation to preserve rare Antarctic archaeological heritage.

Key words
Antarctic heritage; degradation; fungi; taxonomy

INTRODUCTION

Antarctica was the last large territory to be discovered and exploited by humans. Human presence in the region has acquired different characteristics over time. The first groups to arrive in the early 19^th century were sealers from companies in the United States and England, who exploited animal resources on the South Shetland Islands to supply oil and skins to the industrial markets (Barczewski & Maddison 2015BARCZEWSKI S & MADDISON B. 2015. Class and Colonialism in Antarctic Exploration, 1750-1920. Am Hist Rev 120: 1447-1448.). Although historians studied the role of sealers in the discovery of the South Shetland Islands, chronicled their voyages, and discussed the economic relevance of sealing in the region, the efforts made by archaeologists in the last 20 years to study the artifacts left by these groups have contributed to learning more about the lives of ordinary sealers who worked in the region (Zarankin & Senatores 1996ZARANKIN A & SENATORES M. 1996. Informe Campaña Arqueologica Antartica. Peninsula Byers, Isla Livingston, Shetland del Sur. Verano 1995/1996. Buenos Aires: Programa de Estudios Prehistoricos - CONICET., Zarankin et al. 2011ZARANKIN A, HISSA S, SALERNO M, FRONER Y, RADICCHI G, ASSIS L & BATISTA A. 2011. Paisagens em branco: arqueologia e antropologia antárticas - avanços e desafios. Vestígios: Rev Lat-Amer Arqueol Hist 5: 9-52.).

Among the Antarctic microbial communities, fungi have been isolated from a wide variety of locations and different substrates (Rosa et al. 2019ROSA LH, ZANI CL, CANTRELL CL, DUKE SO, VAN DIJCK P, DESIDERI A & ROSA CA. 2019. Fungi in Antarctica: diversity, ecology, effects of climate change, and bioprospection for bioactive compounds. In Rosa LH (Ed), Fungi of Antarctica, Springer, Cham, Switzerland, p. 1-17.). Of more than 1,000 non-lichenised fungi reported in the Antarctic and sub-Antarctic regions, only 2-3% are considered psychrophilic endemic species (growth capacity at temperatures <20 °C) (Bridge & Hughes 2010BRIDGE PD & HUGHES KA. 2010. Conservation issues for Antarctic fungi. Mycol Balc 7: 73-76.). However, among the fungi already reported in Antarctica, those with mesophilic (growth capacity at temperatures between 20-45 °C) temperature profiles or wide temperature tolerance (growth capacity from 0 °C, with maximum growth temperature above ≥ 20 °C) seem to dominate different environments (Rosa et al. 2019ROSA LH, ZANI CL, CANTRELL CL, DUKE SO, VAN DIJCK P, DESIDERI A & ROSA CA. 2019. Fungi in Antarctica: diversity, ecology, effects of climate change, and bioprospection for bioactive compounds. In Rosa LH (Ed), Fungi of Antarctica, Springer, Cham, Switzerland, p. 1-17., 2020a).

In the golden Antarctic exploratory period, called the “Heroic Era”, bases were established, and organic non-Antarctic materials were introduced in Antarctica, including wood, foodstuffs, clothes; together with these materials, exotic microorganisms may have been introduced accidentally (Farrel et al. 2011). Some evidence indicates the presence of these exotic microbes, such as the deterioration of the wood of huts and pieces in recent decades, which have highlighted the need for long-term preservation of these important historic sites (Blanchette et al. 2004BLANCHETTE RA, HELD BW, JURGENS JA, MCNEW DL, HARRINGTON TC, DUNCAN SM & FARRELL RL. 2004. Wood-destroying soft rot fungi in the historic expedition huts of Antarctica. Appl Environ Microbiol 70: 1328-1335., 2010DE MENEZES GC, GODINHO VM, PORTO BA, GONÇALVES VN & ROSA LH. 2017. Antarctomyces pellizariae sp. nov., a new, endemic, blue, snow resident psychrophilic ascomycete fungus from Antarctica. Extremophiles 21: 259-269., Ritchie 2006RITCHIE NA. 2006. Frozen solid: recent archaeological work at Shackleton’s Cape Royd’s hut site (1907-1909), Ross Island, Ross Dependency, Antarctica. In: Paterson A & Casey M (Eds), Volume of Papers in Honour of Judy Birmingham, Australasian Historical Archaeology, p. 39., Held et al. 2006HELD BW, JURGENS JA, DUNCAN SM, FARRELL RL & BLANCHETTE RA. 2006. Assessment of fungal diversity and deterioration in a wooden structure at New Harbor, Antarctica. Polar Biol 29: 526-531., Farrel et al. 2011, Held & Blachette 2017). Held & Blachette (2017) identified the sequences of fungal species reported in temperate regions associated with the historic wood structures on Deception Island, Antarctica, suggesting that these species were probably introduced in construction materials and indicating that human influences and volcanic activity affected the diversity of the detected fungi. However, native Antarctic fungi also can be found in wood and objects in historic huts of Antarctica (Blanchette et al. 2004BLANCHETTE RA, HELD BW, JURGENS JA, MCNEW DL, HARRINGTON TC, DUNCAN SM & FARRELL RL. 2004. Wood-destroying soft rot fungi in the historic expedition huts of Antarctica. Appl Environ Microbiol 70: 1328-1335.), which may contribute to the deterioration of the Antarctic artifacts deposited in collections.

The Byers Peninsula on Livingston Island has the highest concentration of sealing camps in the region (27 sites). Sealers’ camps consisted of stone enclosures and other structures of various shapes, the functions of which remain unknown. In all cases, structures were built using local materials, including stone and whale ribs. Rocky outcrops or caves that provide natural shelters were integrated into the structures. The whale vertebrae served as the seating. The use of foreign materials was restricted to old sails, canvas, or seal skin (in the case of roofs), and wood or whale vertebrae (in the case of beamed structures). It is likely that wood was also obtained from wrecks found on the shores. In general, none of these structures exceeded 15 square m; walls were approximately 1.2 m high. Material remains found in the camps were primarily made of wood and bone, with some textile, metal, ceramic, and glass objects.

Pioneering studies by Blanchette et al. (2004, 2010), Held et al. (2006)HELD BW, JURGENS JA, DUNCAN SM, FARRELL RL & BLANCHETTE RA. 2006. Assessment of fungal diversity and deterioration in a wooden structure at New Harbor, Antarctica. Polar Biol 29: 526-531., Farrell et al. (2011)FARRELL RL, ARENZ BE, DUNCAN SM, HELD BW, JURGENS JA & BLANCHETTE RA. 2011. Introduced and indigenous fungi of the Ross Island historic huts and pristine areas of Antarctica. Polar Biol 34: 1669-1677., and Held & Blanchette (2017)HELD BW & BLANCHETTE RA. 2017. Deception Island, Antarctica, harbors a diverse assemblage of wood decay fungi. Fungal Biol 121: 145-157. detected fungi on different archaeological structures and materials in Antarctica. However, there are no reports on the presence of fungi as contaminants on Antarctic artifacts stocked in museum collections outside of Antarctica. The identification of the microorganisms that act on these rare archaeological pieces may provide important information for conservation and to determine strategies for microbial control and/or suppression. In addition, knowledge of the resident microbial community colonising the objects present in Antarctica might provide interesting archaeological information, such as the detection of non-endemic Antarctic species, which might indicate that people who lived in shelters on Livingston Island (or other Antarctic regions) introduced these non-native Antarctic species in different regions.

Due to the scarcity of documents on the life of sealers in Antarctica, the preservation of archaeological remains, especially those of organised groups that are the most vulnerable, is fundamental for telling the history of this group, which has been excluded from the master narratives (Zarankin & Senatores 1996ZARANKIN A & SENATORES M. 1996. Informe Campaña Arqueologica Antartica. Peninsula Byers, Isla Livingston, Shetland del Sur. Verano 1995/1996. Buenos Aires: Programa de Estudios Prehistoricos - CONICET., Zarankin et al. 2011ZARANKIN A, HISSA S, SALERNO M, FRONER Y, RADICCHI G, ASSIS L & BATISTA A. 2011. Paisagens em branco: arqueologia e antropologia antárticas - avanços e desafios. Vestígios: Rev Lat-Amer Arqueol Hist 5: 9-52.). After the artifacts collection in the field, they take about two months to arrive in Brazil. During transport, the artifacts are stored in the ship’s refrigerated chamber (at a temperature similar to Antarctic conditions of 8 °C). Upon arrival at the archaeological laboratory, the organic artifacts are immediately stored in the refrigerator between 8 °C and 10 °C. However, as the abrupt drying of organic archaeological objects is considered negative for their preservation, the materials are not immediately dried and remain moist. In the refrigerator, archaeological materials are kept between 8 °C and 10 °C with relative humidity above 60%. In contrast, glass or ceramic materials remain on the shelves at room temperature, which ranged from 13 to 28 °C. The favourable conditions of heat, oxygen, and the availability of moisture inside the artifact packaging bags can increase the proliferation of microorganisms. There are some alternatives to control and prevent microbial growth on the objects, such as the use of biocides. However, this alternative is not considered a very suitable mitigation measure because of its toxicity and interference with the interpretation of artifacts due to the addition of foreign substances. A better way to avoid biological colonisation and, consequently, degradation is preventative conservation through the control of environmental conditions. Microorganisms, especially fungi, can cause aesthetic damage to objects when using the substrate for fixation. In addition, microbes can produce pigments and stains that disfigure archaeological objects. Growth activities generate mechanical forces that often result in the detachment, softening, and cracking of the materials. Microbes also use organic material substrates as food and exert biochemical-enzymatic activities that deteriorate organic compounds (such as cellulose, lignin, and keratin) (Urzì & Krumbein 1994URZÌ C & KRUMBEIN WE. 1994. Microbiological impacts on the cultural heritage. In: KRUMBEIN WE et al. (Eds), Durability and Change: The Science, Responsibility, and Cost of Sustaining Cultural Heritage New York: J Wiley & Sons, New York, USA, p. 107-135.). Biological disinfection is very important in the archaeological sites of Livingston Island, in which remnants of organic nature are predominant. In the current study, we chose wet and dry Antarctic archaeological artifacts from the early 19^th century stored inside refrigerators between 8°C and 10°C and room temperature (25 °C) that displayed apparent mycelial growth to identify the resident fungal species and to understand how temperature and humidity conditions may affect microbial colonisation of the objects.

METHODS

Archaeological sealers’ artifacts

Archaeological excavations from sealer sites from the beginning obtained of the 19^th century were conducted during fieldwork at Byers Peninsula, Livingston Island, South Shetland Islands in different years (Table I; Figure 1), which allowed the recovery of an important collection of artifacts. The conservation of these items is fundamental to preserve the histories of sealer groups; they were sampled using only physical protocols to guarantee the integrity of the recovered remains, especially in packaging and conditioning. However, the collectors did not use adequate protocols to avoid possible biological contamination of the objects. The artifacts were placed in non-sterilised polyethylene bag with flexible polyethylene foam (which is inert and provides mechanical protection and greater stability to the objects). The items were transported from the field inside rigid polyethylene boxes to Brazil, where they were stocked in the archaeological collection. The collections and studies were authorized by the Secretariat of the Antarctic Treaty and by Brazilian Antarctic Program (PROANTAR).

Figure 1
Location where the archaeological artifacts were sampled. (a) Antarctic Peninsula, (b) Livingston Island, and Byers Peninsula (inside the red circle). (c, d) Examples of archaeological sites where the artefacts were sampled. Photos (c) belong to A. Zarankin.

Figure 2
Antarctic sealer’s artifacts from which fungi were recovered. (a) Wood probably reused for food or animal processing; (b) whale bone (vertebrae) used as internal furniture in the sealer hut, especially in a chair or improvised table used as a food plate; (c) wood fragment that appears to be part of a whaling boat; (d) fabric made of tricot with fibers of animal origin (wool); and (e) fabric/skin/soil. Red arrows show the presence of fungal mycelia.

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Table I
Artefacts sampled in the archaeological sealer site on Byers Peninsula, Livingston Island, South Shetland Island, Antarctica.

Fungal isolation

All the archaeological materials were processed under a laminar flow hood to avoid external air contamination. Using sterile disposable loops, smears were taken from different locations of the artifact materials. The samples were inoculated on Sabouraud agar (Himedia, Mumbai, India) containing 200 µg mL^-1 of chloramphenicol (Sigma, St. Louis, MO, USA) and incubated at 10 or 25 °C (mimicking the storage temperature of the objects) for 30 days. For each archaeological material, three different disposable loops and three Petri dishes were used. The fungi were purified in new Petri dishes containing Sabouraud agar and deposited in the Collection of Microorganisms and Cells of the Universidade Federal de Minas Gerais, Brazil, under the code UFMGCB in cryotubes at −80 °C and in distillate-sterilized water (Castellani 1967CASTELLANI A. 1967. Maintenance and cultivation of common pathogenic fungi in distilled water. J Trop Med Hygien 42: 181-184.) at room temperature.

Fungal identification

The protocol for DNA extraction was described previously by Rosa et al. (2009)ROSA LH, VAZ ABM, CALIGIORNE RB, CAMPOLINA S & ROSA CA. 2009. Endophytic fungi associated with the Antarctic Grass Deschampsia antarctica Desv. (Poaceae). Polar Biol 32: 161-167.. Amplification of the transcribed internal spacer (ITS-5.8S) region for filamentous fungi was performed according to Rosa et al. (2009)ROSA LH, VAZ ABM, CALIGIORNE RB, CAMPOLINA S & ROSA CA. 2009. Endophytic fungi associated with the Antarctic Grass Deschampsia antarctica Desv. (Poaceae). Polar Biol 32: 161-167. using the primers ITS1 and ITS4 (White et al. 1990WHITE TJ, BRUNS TD & LEE SB. 1990. Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics. In: Innis NA et al. (Eds), PCR protocols: a guide to methods and applications. Academic Press, San Diego, USA, p. 315-322.). However, sequencing of the ITS region may fail to recognize some fungal genera. For this reason, the ribosomal polymerase B2 (Houbraken et al. 2012HOUBRAKEN J, FRISVAD JC, SEIFERT KA, OVERY DP, TUTHILL DM, VALDEZ JG & SAMSON RA. 2012. New penicillin-producing Penicillium species and an overview of section Chrysogena. Persoonia 29: 78-100.) sequence, which is considered promising for a one-gene phylogeny (Malkus et al. 2006MALKUS A, CHANG PFL, ZUZGA SM, CHUNG KR, SHAO J, CUNFER BM, ARSENIUK E & UENG PP. 2006. RNA polymerase II gene (RPB2) encoding the second largest protein subunit in Phaeosphaeria nodorum and P. avenaria. Mycological Res 110: 1152-1164.), was used to elucidate the taxonomic positions of the inconclusive taxa identified using ITS sequences. The consensus sequence was aligned with all sequences from related species retrieved from the GenBank database of the National Center for Biotechnology Information using the Basic Locus Search Alignment Tool (BLASTn) program (Altschul et al. 1997ALTSCHUL SF, MADDEN TL, SCHAFFER AA, ZHANG JH, ZHANG Z, MILLER W & LIPMAN DJ. 1997. Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Res 25: 3389-3402.). Fungal isolates with query coverage and identity ≥ 99% were considered to represent the same taxon. However, taxa that displayed query coverage and identities ≤98% or an inconclusive taxonomic position after the BLASTn analysis were subjected to phylogenetic ITS and polymerase II gene analysis, with estimations conducted using MEGA Version 5.0 (Tamura et al. 2011TAMURA K, PETERSON D, PETERSON N, STECHER G, NEI M & KUMAR S. 2011. MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Mol Biol Evol 28: 2731-2739.). Representative consensus sequences of the fungal taxa were deposited in the GenBank database (Table II). Information about fungal classification generally followed the databases of Kirk et al. (2011)KIRK PM, CANNON PF, MINTER DW & STALPERS JA. 2011. Dictionary of the Fungi, 10th ed., Wallingford: CAB International, 784 p., MycoBank (http://www.mycobank.org), and the Index Fungorum (http://www.indexfungorum.org). Venn diagrams were prepared according to Bardou et al. (2014)BARDOU P, MARIETTE J, ESCUDIé F, DJEMIEL C & KLOPP C. 2014. Jvenn: an interactive Venn diagram viewer. BMC Bioinformatics 15: 293. to illustrate the comparison of fungal assemblages associated with artifacts with high sampling.

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Table II
Fungi identified from archaeological artifacts sampled on Livingston Island, South Shetland Islands, Antarctica.

RESULTS

Fungal taxonomy and distribution

Twenty fungal isolates were obtained from different archaeological objects, which were identified only by molecular approach to represent nine taxa of the genera Antarctomyces, Linnemannia, Penicillium, Mortierella, Talaromyces, and Trichoderma (Table II). Despite to display ITS query coverage and/or identities ≥ 99% in the BLASTn analysis, Antarctomyces, Linnemannia, Penicillium, Mortierella, and Trichoderma showed distant phylogenetic proximity when compared with known fungal sequences deposited in the GenBank. Due the inconclusive phylogenetic identification, these fungi were identified in genera level (Supplementary Material – Figure S1). The fungal genera varied across different artifact materials and storage temperatures (Figure 3). The genus Penicillium was predominant on the items stored between 8 °C and 10 °C and 25 °C. Talaromyces domesticus was detected only in wood stored at 25 °C. In contrast, Antarctomyces, Linnemania, Mortierella, and Trichoderma occurred on different artifacts, but only in those stored between 8 °C and 10 °C. However, at the species level, no single taxon was detected in more than one object. In addition, when stored between 8 °C and 10 °C, the endemic Antarctic fungus Antarctomyces psychrotrophicus and cold-tolerant Mortierella sp. were detected on the tissue artifact, Trichoderma sp. 1 and sp. 2 on leather, and Linnemannia sp. on the whale bone used as a food support accessory.

Figure 3
Similarities of fungal genera detected on the different (a) archaeological sealer’s Antarctic artifact materials and (b) artefact storage temperatures.

DISCUSSION

The objects of the Antarctic archaeological sealer’s sites were dated using different elements that indicate their national origin, manufacturing techniques, uses, and reuse. The samples chosen for our study did not have specific information that allowed us to make this association directly. However, because of their proximity to materials such as kaolin pipes, glass bottles, and metal buttons, it is possible to establish an approximate date for these pieces between 1820 and 1840 (Soares et al. 2016SOARES FC, DA ROSA LAS, JÓIA TC & PEÑA WLS. 2016. A (des) Construção da embriaguez em solos Antárticos. Comida, Cultura e Sociedade: Arqueologia da Alimentação no Mundo Moderno, 139-168., 2019SOARES FC, DE AMORIM CL & PENA WLS. 2019. Um fio de fumaça nos mares do sul cachimbos de caulim e masculinidades nas Ilhas Shetland do Sul (séculos XVIII e XIX). Rev Arqueol 32: 129-159., Soares & Gardiman 2017SOARES FC & GARDIMAN GG. 2017. Mais uma dose: análise arqueobotânica do consumo de cerveja nas Shetland do Sul (Antártica). Rev Habitus 15: 273-299.). After the mycological study, our results displayed the presence of different fungal genera represented by cosmopolitan mesophiles (Penicillium, Talaromyces and Trichoderma), cold-adapted species (Linnemannia and Mortierella), and endemic (Antarctomyces) fungi on the surface of collected artifacts stored at room temperature and cold temperatures in Brazil.

Penicillium includes cosmopolitan species detected in Antarctica (Rosa et al. 2020bROSA LH, DA SILVA TH, OGAKI MB, PINTO OHB, STECH M, CONVEY P, CARVALHO- SILVA M, ROSA CA & CâMARA PE. 2020b. DNA metabarcoding uncovers fungal diversity in soils of protected and non-protected areas on Deception Island, Antarctica. Sci Rep 10: 21986.), where they are broadly distributed, indicating their versatile adaptability to the extreme conditions of the continent; furthermore, they have been reported in soil, snow, air, ice, seawater and marine sediments, freshwater and lake sediments, plants, and animals (Rosa et al. 2019ROSA LH, ZANI CL, CANTRELL CL, DUKE SO, VAN DIJCK P, DESIDERI A & ROSA CA. 2019. Fungi in Antarctica: diversity, ecology, effects of climate change, and bioprospection for bioactive compounds. In Rosa LH (Ed), Fungi of Antarctica, Springer, Cham, Switzerland, p. 1-17., 2020aROSA LH, PINTO OHB, CONVEY P, CARVALHO-SILVA M, ROSA CA & CâMARA PEAS. 2020a. DNA metabarcoding to assess the diversity of airborne fungi present over Keller Peninsula, King George Island, Antarctica. Microb Ecol 82: 165-172., cROSA LH, PINTO OHB, ŠANTL-TEMKIV T, CONVEY P, CARVALHO-SILVA M, ROSA CA & CâMARA PE. 2020c. DNA metabarcoding of fungal diversity in air and snow of Livingston Island, South Shetland Islands, Antarctica. Sci Rep 10: 21793.). In addition, Pencillium has been detected in deteriorating wooden structures in Antarctica (Held et al. 2006HELD BW, JURGENS JA, DUNCAN SM, FARRELL RL & BLANCHETTE RA. 2006. Assessment of fungal diversity and deterioration in a wooden structure at New Harbor, Antarctica. Polar Biol 29: 526-531.). Talaromyces, also reported as Byssochlamys, includes cosmopolitan species present in soils and indoor environments, which have been reported in Antarctic rocks (Gonçalves et al. 2017GONÇALVES VN, OLIVEIRA FS, CARVALHO CR, SCHAEFER CE, ROSA CA & ROSA LH. 2017. Antarctic rocks from continental Antarctica as source of potential human opportunistic fungi. Extremophiles 21: 851-860.). Trichoderma (hyphomycetes) shelter species are ubiquitous in the environment, especially in soils (Samuels 1996SAMUELS GJ. 1996. Trichoderma: a review of biology and systematics of the genus. Mycol Res 100: 923-935.). In Antarctica, Trichoderma taxa have been detected in different environments and habitats, such as glacial ice (Jacobs et al. 1964JACOBS PH, TAYLOR HC & SHAFER JC. 1964. Studies of fungi at Amundsen-Scott IGY South Pole Base. Arch Dermatol 89: 117-123.), plants (McRae & Seppelt 1999MCRAE CF & SEPPELT RD. 1999. Filamentous fungi of the Windmill Islands, continental Antarctica. Effect of water content in moss turves on fungal diversity. Polar Biol 22: 389-394.), marine sediment (Ren et al. 2009REN J, XUE C, TIAN L, XU M, CHEN J, DENG Z, PROKSCH P & LIN W. 2009. Asperelines A-F, peptaibols from the marine-derived fungus Trichoderman asperellum. J Nat Prod 72: 1036-1044.), soils (Kochkina et al. 2019KOCHKINA GA, IVANUSHKINA NE, LUPACHEV AV, STARODUMOVA IP, VASILENKO OV & OZERSKAYA SM. 2019. Diversity of mycelial fungi in natural and human-affected Antarctic soils. Polar Biol 42: 1-18.), freshwater lakes (Gonçalves et al. 2012GONÇALVES VN, VAZ AB, ROSA CA, ROSA LH. 2012. Diversity and distribution of fungal communities in lakes of Antarctica. FEMS Microbiol Ecol 82: 459-471.), and permafrost (Kochkina et al. 2012KOCHKINA G, IVANUSHKINA N, OZERSKAYA S, CHIGINEVA N, VASILENKO O, FIRSOV S, SPIRINA E & GILICHINSKY D. 2012. Ancient fungi in Antarctic permafrost environments. FEMS Microbiol Ecol 82: 501-509.).

The genus Mortierella seems to be ubiquitous in Antarctica and has been reported mainly in soil (Newsham et al. 2018NEWSHAM KK, GARNETT MH, ROBINSON CH & COX F. 2018. Discrete taxa of saprotrophic fungi respire different ages of carbon from Antarctic soils. Sci Rep 8: 7866., Gomes et al. 2018GOMES ECQ ET AL. 2018. Cultivable fungi present in Antarctic soils: taxonomy, phylogeny, diversity, and bioprospecting of antiparasitic and herbicidal metabolites. Extremophiles 22: 381-393.), snow (de Menezes et al. 2019DE MENEZES GC, AMORIM SS, GONÇALVES VN, GODINHO VM, SIMÕES JC, ROSA CA & ROSA LH. 2019. Diversity, distribution, and ecology of fungi in the seasonal snow of Antarctica. Microorganisms 7: 445.), and plants (Melo et al. 2014MELO IS, SANTOS SN, ROSA LH, PARMA MM, SILVA LJ, QUEIROZ SC & PELLIZARI VH. 2014. Isolation and biological activities of an endophytic Mortierella alpina strain from the Antarctic moss Schistidium antarctici. Extremophiles 18: 15-23., Gonçalves et al. 2016GONÇALVES VN ET AL. 2016. Fungi associated with rocks of the Atacama Desert: taxonomy, distribution, diversity, ecology and bioprospection for bioactive compounds. Environ Microbiol 18: 232-245., Rosa et al. 2020d). Antarctomyces is an endemic Antarctic genus with two reported species: A. psychrotrophicus and A. pellizariae, which were originally isolated from soil and snow, respectively, on King George Island of the South Shetland Islands (Stchigel et al. 2001STCHIGEL AM, JOSEP CANO, MAC CORMACK W & GUARRO J. 2001. Antarctomyces psychrotrophicus gen. et sp. nov., a new ascomycete from Antarctica. Mycol Res 105: 377-382., de Menezes et al. 2017DE MENEZES GC, GODINHO VM, PORTO BA, GONÇALVES VN & ROSA LH. 2017. Antarctomyces pellizariae sp. nov., a new, endemic, blue, snow resident psychrophilic ascomycete fungus from Antarctica. Extremophiles 21: 259-269.). A. psychrotrophicus has already been identified in different habitats in Antarctica, including soils (Stchigel et al. 2001STCHIGEL AM, JOSEP CANO, MAC CORMACK W & GUARRO J. 2001. Antarctomyces psychrotrophicus gen. et sp. nov., a new ascomycete from Antarctica. Mycol Res 105: 377-382., Gomes et al. 2018GOMES ECQ ET AL. 2018. Cultivable fungi present in Antarctic soils: taxonomy, phylogeny, diversity, and bioprospecting of antiparasitic and herbicidal metabolites. Extremophiles 22: 381-393.), plants (Rosa et al. 2009ROSA LH, VAZ ABM, CALIGIORNE RB, CAMPOLINA S & ROSA CA. 2009. Endophytic fungi associated with the Antarctic Grass Deschampsia antarctica Desv. (Poaceae). Polar Biol 32: 161-167., Coelho et al. 2021COELHO LDC, CARVALHO CR, ROSA CA & ROSA LH. 2021. Diversity, distribution, and xerophilic tolerance of cultivable fungi associated with the Antarctic angiosperms. Polar Biol 44: 379-388.), lake freshwater (Gonçalves et al. 2012GONÇALVES VN, VAZ AB, ROSA CA, ROSA LH. 2012. Diversity and distribution of fungal communities in lakes of Antarctica. FEMS Microbiol Ecol 82: 459-471.), and lake sediments (Ogaki et al. 2020OGAKI MB ET AL. 2020. Diversity and bioprospecting of cultivable fungal assemblages in sediments of lakes in the Antarctic Peninsula. Fungal Biol 124: 601-611.).

Furthermore, some details regarding the sampling, transportation, and storage of the objects in the collection indicate failure in the process of microbiological sterilisation, which can contribute to further microbial attack and, consequently, material degradation. Owing to logistical limitations, the boxes with artifacts did not remain refrigerated throughout the period of transportation from Antarctica to Brazil (approximately 3 months). The boxes containing pieces remained in the hold of the ship, which was affected by variations in temperature and humidity. When the artifacts arrived at the final destination in the laboratory (Brazil), they were handled with latex gloves, cleaned superficially with soft brushes, and photographed for inventory. The objects were removed from the plastic bags and placed in new non-sterilised bags. Finally, the artifacts were stored in the laboratory collection and eventually manipulated for further analysis. Some objects were stored in refrigerators between 8 °C and 10 °C (2012.0848, 2011.0316), while others remained outside at 25 °C (2017.1395, 2012.888, 2014.1261). The storage temperature of the artifacts may have directly interfered with the fungi obtained, as well as the type of material that makes up the artifacts. However, due the capability of these Antarctic fungi survive and/or growth under the cold temperatures of Antarctica, the refrigeration above 0°C could not prevent their metabolic activities on the artifacts.

Our results showed that Antarctic artifacts harbour different fungal genera represented by cosmopolitan mesophilic, cold-tolerant, and endemic psychrophilic taxa. It is possible that mesophilic taxa originated in Europe and were transported to Antarctica via these items, where they could have undergone selection to the extreme environmental conditions and survived over the years as spores or resistant mycelia on artifacts found in the archaeological sites. The mesophilic fungi might have contaminated the artifacts in situ as resident taxa, during sampling, transport, and/or storage in the laboratory collection or represent dormant but viable form capable to grow on the objects, which reinforces the need for preventive and effective microbiological sterilisation throughout the artifacts recovery process to avoid exogenous microbial contamination. Moreover, the detection of cold-tolerant and endemic fungi shows that these fungi, when stored between 8 °C and 10 °C, continue growing on the pieces, which may supply them with organic nutrients and, consequently, accelerate the degradation of the objects in the museum collection. The identification of the fungi present on the archaeological artifacts represents the first step in controlling their growth, contamination, and further biological degradation, which is a common problem in the proper preservation of organic Antarctic artifacts. As the fungal community detected on the items was represented by mesophilic, cold-tolerant, and psychrophilic aerobic species, some preventive steps should be adopted to avoid further microbial contamination. Sterilised microbiological conditions can be followed, such as the use of sterilised gloves to handle pieaces during fieldwork, use of sterilised bags in which to place artifacts after sampling, sterilisation of flexible polyethylene foam and plastic boxes used to protect the objects, temperature control (≤10 °C) during the transportation process until arrival in Brazil (or other countries), handling of materials using sterilised gloves and bags, and storage under low air moisture and anaerobic conditions. This preventive protocol may represent a better alternative to avoid microbial proliferation on artifacts in order to preserve this rare Antarctic archaeological heritage.

ACKNOWLEDGMENTS

This study received financial support from Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq), Fundação de Amparo à Pesquisa do Estado de Minas Gerais (FAPEMIG), Coordenação de Aperfeiçoamento de Pessoal de Nível Superior-Brasil (CAPES), Programa Antártico Brasileiro (PROANTAR), and Instituto Nacional da Ciência e Tecnologia da Criosfera (INCT Criosfera). GCA de Menezes’ scholarship was supported by CNPq (151195/2019-6). The collections and studies were authorized by the Secretariat of the Antarctic Treaty and by PROANTAR.

REFERENCES

ALTSCHUL SF, MADDEN TL, SCHAFFER AA, ZHANG JH, ZHANG Z, MILLER W & LIPMAN DJ. 1997. Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Res 25: 3389-3402.
BARCZEWSKI S & MADDISON B. 2015. Class and Colonialism in Antarctic Exploration, 1750-1920. Am Hist Rev 120: 1447-1448.
BARDOU P, MARIETTE J, ESCUDIé F, DJEMIEL C & KLOPP C. 2014. Jvenn: an interactive Venn diagram viewer. BMC Bioinformatics 15: 293.
BLANCHETTE RA, HELD BW, ARENZ BE, JURGENS JA, BALTES NJ, DUNCAN SM & FARRELL RL. 2010. An Antarctic hot spot for fungi at Shackleton’s historic hut on Cape Royds. Microb Ecol 60: 29-38.
BLANCHETTE RA, HELD BW, JURGENS JA, MCNEW DL, HARRINGTON TC, DUNCAN SM & FARRELL RL. 2004. Wood-destroying soft rot fungi in the historic expedition huts of Antarctica. Appl Environ Microbiol 70: 1328-1335.
BRIDGE PD & HUGHES KA. 2010. Conservation issues for Antarctic fungi. Mycol Balc 7: 73-76.
CASTELLANI A. 1967. Maintenance and cultivation of common pathogenic fungi in distilled water. J Trop Med Hygien 42: 181-184.
COELHO LDC, CARVALHO CR, ROSA CA & ROSA LH. 2021. Diversity, distribution, and xerophilic tolerance of cultivable fungi associated with the Antarctic angiosperms. Polar Biol 44: 379-388.
DE MENEZES GC, AMORIM SS, GONÇALVES VN, GODINHO VM, SIMÕES JC, ROSA CA & ROSA LH. 2019. Diversity, distribution, and ecology of fungi in the seasonal snow of Antarctica. Microorganisms 7: 445.
DE MENEZES GC, GODINHO VM, PORTO BA, GONÇALVES VN & ROSA LH. 2017. Antarctomyces pellizariae sp. nov., a new, endemic, blue, snow resident psychrophilic ascomycete fungus from Antarctica. Extremophiles 21: 259-269.
FARRELL RL, ARENZ BE, DUNCAN SM, HELD BW, JURGENS JA & BLANCHETTE RA. 2011. Introduced and indigenous fungi of the Ross Island historic huts and pristine areas of Antarctica. Polar Biol 34: 1669-1677.
GOMES ECQ ET AL. 2018. Cultivable fungi present in Antarctic soils: taxonomy, phylogeny, diversity, and bioprospecting of antiparasitic and herbicidal metabolites. Extremophiles 22: 381-393.
GONÇALVES VN ET AL. 2016. Fungi associated with rocks of the Atacama Desert: taxonomy, distribution, diversity, ecology and bioprospection for bioactive compounds. Environ Microbiol 18: 232-245.
GONÇALVES VN, OLIVEIRA FS, CARVALHO CR, SCHAEFER CE, ROSA CA & ROSA LH. 2017. Antarctic rocks from continental Antarctica as source of potential human opportunistic fungi. Extremophiles 21: 851-860.
GONÇALVES VN, VAZ AB, ROSA CA, ROSA LH. 2012. Diversity and distribution of fungal communities in lakes of Antarctica. FEMS Microbiol Ecol 82: 459-471.
HELD BW & BLANCHETTE RA. 2017. Deception Island, Antarctica, harbors a diverse assemblage of wood decay fungi. Fungal Biol 121: 145-157.
HELD BW, JURGENS JA, DUNCAN SM, FARRELL RL & BLANCHETTE RA. 2006. Assessment of fungal diversity and deterioration in a wooden structure at New Harbor, Antarctica. Polar Biol 29: 526-531.
HOUBRAKEN J, FRISVAD JC, SEIFERT KA, OVERY DP, TUTHILL DM, VALDEZ JG & SAMSON RA. 2012. New penicillin-producing Penicillium species and an overview of section Chrysogena. Persoonia 29: 78-100.
JACOBS PH, TAYLOR HC & SHAFER JC. 1964. Studies of fungi at Amundsen-Scott IGY South Pole Base. Arch Dermatol 89: 117-123.
KIRK PM, CANNON PF, MINTER DW & STALPERS JA. 2011. Dictionary of the Fungi, 10th ed., Wallingford: CAB International, 784 p.
KOCHKINA G, IVANUSHKINA N, OZERSKAYA S, CHIGINEVA N, VASILENKO O, FIRSOV S, SPIRINA E & GILICHINSKY D. 2012. Ancient fungi in Antarctic permafrost environments. FEMS Microbiol Ecol 82: 501-509.
KOCHKINA GA, IVANUSHKINA NE, LUPACHEV AV, STARODUMOVA IP, VASILENKO OV & OZERSKAYA SM. 2019. Diversity of mycelial fungi in natural and human-affected Antarctic soils. Polar Biol 42: 1-18.
MALKUS A, CHANG PFL, ZUZGA SM, CHUNG KR, SHAO J, CUNFER BM, ARSENIUK E & UENG PP. 2006. RNA polymerase II gene (RPB2) encoding the second largest protein subunit in Phaeosphaeria nodorum and P. avenaria. Mycological Res 110: 1152-1164.
MCRAE CF & SEPPELT RD. 1999. Filamentous fungi of the Windmill Islands, continental Antarctica. Effect of water content in moss turves on fungal diversity. Polar Biol 22: 389-394.
MELO IS, SANTOS SN, ROSA LH, PARMA MM, SILVA LJ, QUEIROZ SC & PELLIZARI VH. 2014. Isolation and biological activities of an endophytic Mortierella alpina strain from the Antarctic moss Schistidium antarctici. Extremophiles 18: 15-23.
NEWSHAM KK, GARNETT MH, ROBINSON CH & COX F. 2018. Discrete taxa of saprotrophic fungi respire different ages of carbon from Antarctic soils. Sci Rep 8: 7866.
OGAKI MB ET AL. 2020. Diversity and bioprospecting of cultivable fungal assemblages in sediments of lakes in the Antarctic Peninsula. Fungal Biol 124: 601-611.
REN J, XUE C, TIAN L, XU M, CHEN J, DENG Z, PROKSCH P & LIN W. 2009. Asperelines A-F, peptaibols from the marine-derived fungus Trichoderman asperellum. J Nat Prod 72: 1036-1044.
RITCHIE NA. 2006. Frozen solid: recent archaeological work at Shackleton’s Cape Royd’s hut site (1907-1909), Ross Island, Ross Dependency, Antarctica. In: Paterson A & Casey M (Eds), Volume of Papers in Honour of Judy Birmingham, Australasian Historical Archaeology, p. 39.
ROSA LH, DA SILVA TH, OGAKI MB, PINTO OHB, STECH M, CONVEY P, CARVALHO- SILVA M, ROSA CA & CâMARA PE. 2020b. DNA metabarcoding uncovers fungal diversity in soils of protected and non-protected areas on Deception Island, Antarctica. Sci Rep 10: 21986.
ROSA LH, PINTO OHB, CONVEY P, CARVALHO-SILVA M, ROSA CA & CâMARA PEAS. 2020a. DNA metabarcoding to assess the diversity of airborne fungi present over Keller Peninsula, King George Island, Antarctica. Microb Ecol 82: 165-172.
ROSA LH, PINTO OHB, ŠANTL-TEMKIV T, CONVEY P, CARVALHO-SILVA M, ROSA CA & CâMARA PE. 2020c. DNA metabarcoding of fungal diversity in air and snow of Livingston Island, South Shetland Islands, Antarctica. Sci Rep 10: 21793.
ROSA LH, SOUSA JRP, DE MENEZES GCA, COSTA CL, CARVALHO-SILVA M CONVEY P & CâMARA PEAS. 2020d. Opportunistic fungi found in fairy rings are present on different moss species in the Antarctic Peninsula. Polar Biol 43: 587-596.
ROSA LH, VAZ ABM, CALIGIORNE RB, CAMPOLINA S & ROSA CA. 2009. Endophytic fungi associated with the Antarctic Grass Deschampsia antarctica Desv. (Poaceae). Polar Biol 32: 161-167.
ROSA LH, ZANI CL, CANTRELL CL, DUKE SO, VAN DIJCK P, DESIDERI A & ROSA CA. 2019. Fungi in Antarctica: diversity, ecology, effects of climate change, and bioprospection for bioactive compounds. In Rosa LH (Ed), Fungi of Antarctica, Springer, Cham, Switzerland, p. 1-17.
SAMUELS GJ. 1996. Trichoderma: a review of biology and systematics of the genus. Mycol Res 100: 923-935.
SOARES FC, DA ROSA LAS, JÓIA TC & PEÑA WLS. 2016. A (des) Construção da embriaguez em solos Antárticos. Comida, Cultura e Sociedade: Arqueologia da Alimentação no Mundo Moderno, 139-168.
SOARES FC, DE AMORIM CL & PENA WLS. 2019. Um fio de fumaça nos mares do sul cachimbos de caulim e masculinidades nas Ilhas Shetland do Sul (séculos XVIII e XIX). Rev Arqueol 32: 129-159.
SOARES FC & GARDIMAN GG. 2017. Mais uma dose: análise arqueobotânica do consumo de cerveja nas Shetland do Sul (Antártica). Rev Habitus 15: 273-299.
STCHIGEL AM, JOSEP CANO, MAC CORMACK W & GUARRO J. 2001. Antarctomyces psychrotrophicus gen. et sp. nov., a new ascomycete from Antarctica. Mycol Res 105: 377-382.
TAMURA K, PETERSON D, PETERSON N, STECHER G, NEI M & KUMAR S. 2011. MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Mol Biol Evol 28: 2731-2739.
URZÌ C & KRUMBEIN WE. 1994. Microbiological impacts on the cultural heritage. In: KRUMBEIN WE et al. (Eds), Durability and Change: The Science, Responsibility, and Cost of Sustaining Cultural Heritage New York: J Wiley & Sons, New York, USA, p. 107-135.
WHITE TJ, BRUNS TD & LEE SB. 1990. Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics. In: Innis NA et al. (Eds), PCR protocols: a guide to methods and applications. Academic Press, San Diego, USA, p. 315-322.
ZARANKIN A, HISSA S, SALERNO M, FRONER Y, RADICCHI G, ASSIS L & BATISTA A. 2011. Paisagens em branco: arqueologia e antropologia antárticas - avanços e desafios. Vestígios: Rev Lat-Amer Arqueol Hist 5: 9-52.
ZARANKIN A & SENATORES M. 1996. Informe Campaña Arqueologica Antartica. Peninsula Byers, Isla Livingston, Shetland del Sur. Verano 1995/1996. Buenos Aires: Programa de Estudios Prehistoricos - CONICET.

SUPPLEMENTARY MATERIAL

Figure S1.

Publication Dates

Publication in this collection
11 Mar 2022
Date of issue
2022

History

Received
11 Feb 2021
Accepted
27 July 2021

This is an open-access article distributed under the terms of the Creative Commons Attribution License

[1] ALTSCHUL SF, MADDEN TL, SCHAFFER AA, ZHANG JH, ZHANG Z, MILLER W & LIPMAN DJ. 1997. Gapped BLAST and PSI-BLAST: a new generation of protein database search programs. Nucleic Acids Res 25: 3389-3402.

[2] BARCZEWSKI S & MADDISON B. 2015. Class and Colonialism in Antarctic Exploration, 1750-1920. Am Hist Rev 120: 1447-1448.

[3] BARDOU P, MARIETTE J, ESCUDIé F, DJEMIEL C & KLOPP C. 2014. Jvenn: an interactive Venn diagram viewer. BMC Bioinformatics 15: 293.

[4] BLANCHETTE RA, HELD BW, ARENZ BE, JURGENS JA, BALTES NJ, DUNCAN SM & FARRELL RL. 2010. An Antarctic hot spot for fungi at Shackleton’s historic hut on Cape Royds. Microb Ecol 60: 29-38.

[5] BLANCHETTE RA, HELD BW, JURGENS JA, MCNEW DL, HARRINGTON TC, DUNCAN SM & FARRELL RL. 2004. Wood-destroying soft rot fungi in the historic expedition huts of Antarctica. Appl Environ Microbiol 70: 1328-1335.

[6] BRIDGE PD & HUGHES KA. 2010. Conservation issues for Antarctic fungi. Mycol Balc 7: 73-76.

[7] CASTELLANI A. 1967. Maintenance and cultivation of common pathogenic fungi in distilled water. J Trop Med Hygien 42: 181-184.

[8] COELHO LDC, CARVALHO CR, ROSA CA & ROSA LH. 2021. Diversity, distribution, and xerophilic tolerance of cultivable fungi associated with the Antarctic angiosperms. Polar Biol 44: 379-388.

[9] DE MENEZES GC, AMORIM SS, GONÇALVES VN, GODINHO VM, SIMÕES JC, ROSA CA & ROSA LH. 2019. Diversity, distribution, and ecology of fungi in the seasonal snow of Antarctica. Microorganisms 7: 445.

[10] DE MENEZES GC, GODINHO VM, PORTO BA, GONÇALVES VN & ROSA LH. 2017. Antarctomyces pellizariae sp. nov., a new, endemic, blue, snow resident psychrophilic ascomycete fungus from Antarctica. Extremophiles 21: 259-269.

[11] FARRELL RL, ARENZ BE, DUNCAN SM, HELD BW, JURGENS JA & BLANCHETTE RA. 2011. Introduced and indigenous fungi of the Ross Island historic huts and pristine areas of Antarctica. Polar Biol 34: 1669-1677.

[12] GOMES ECQ ET AL. 2018. Cultivable fungi present in Antarctic soils: taxonomy, phylogeny, diversity, and bioprospecting of antiparasitic and herbicidal metabolites. Extremophiles 22: 381-393.

[13] GONÇALVES VN ET AL. 2016. Fungi associated with rocks of the Atacama Desert: taxonomy, distribution, diversity, ecology and bioprospection for bioactive compounds. Environ Microbiol 18: 232-245.

[14] GONÇALVES VN, OLIVEIRA FS, CARVALHO CR, SCHAEFER CE, ROSA CA & ROSA LH. 2017. Antarctic rocks from continental Antarctica as source of potential human opportunistic fungi. Extremophiles 21: 851-860.

[15] GONÇALVES VN, VAZ AB, ROSA CA, ROSA LH. 2012. Diversity and distribution of fungal communities in lakes of Antarctica. FEMS Microbiol Ecol 82: 459-471.

[16] HELD BW & BLANCHETTE RA. 2017. Deception Island, Antarctica, harbors a diverse assemblage of wood decay fungi. Fungal Biol 121: 145-157.

[17] HELD BW, JURGENS JA, DUNCAN SM, FARRELL RL & BLANCHETTE RA. 2006. Assessment of fungal diversity and deterioration in a wooden structure at New Harbor, Antarctica. Polar Biol 29: 526-531.

[18] HOUBRAKEN J, FRISVAD JC, SEIFERT KA, OVERY DP, TUTHILL DM, VALDEZ JG & SAMSON RA. 2012. New penicillin-producing Penicillium species and an overview of section Chrysogena. Persoonia 29: 78-100.

[19] JACOBS PH, TAYLOR HC & SHAFER JC. 1964. Studies of fungi at Amundsen-Scott IGY South Pole Base. Arch Dermatol 89: 117-123.

[20] KIRK PM, CANNON PF, MINTER DW & STALPERS JA. 2011. Dictionary of the Fungi, 10th ed., Wallingford: CAB International, 784 p.

[21] KOCHKINA G, IVANUSHKINA N, OZERSKAYA S, CHIGINEVA N, VASILENKO O, FIRSOV S, SPIRINA E & GILICHINSKY D. 2012. Ancient fungi in Antarctic permafrost environments. FEMS Microbiol Ecol 82: 501-509.

[22] KOCHKINA GA, IVANUSHKINA NE, LUPACHEV AV, STARODUMOVA IP, VASILENKO OV & OZERSKAYA SM. 2019. Diversity of mycelial fungi in natural and human-affected Antarctic soils. Polar Biol 42: 1-18.

[23] MALKUS A, CHANG PFL, ZUZGA SM, CHUNG KR, SHAO J, CUNFER BM, ARSENIUK E & UENG PP. 2006. RNA polymerase II gene (RPB2) encoding the second largest protein subunit in Phaeosphaeria nodorum and P. avenaria. Mycological Res 110: 1152-1164.

[24] MCRAE CF & SEPPELT RD. 1999. Filamentous fungi of the Windmill Islands, continental Antarctica. Effect of water content in moss turves on fungal diversity. Polar Biol 22: 389-394.

[25] MELO IS, SANTOS SN, ROSA LH, PARMA MM, SILVA LJ, QUEIROZ SC & PELLIZARI VH. 2014. Isolation and biological activities of an endophytic Mortierella alpina strain from the Antarctic moss Schistidium antarctici. Extremophiles 18: 15-23.

[26] NEWSHAM KK, GARNETT MH, ROBINSON CH & COX F. 2018. Discrete taxa of saprotrophic fungi respire different ages of carbon from Antarctic soils. Sci Rep 8: 7866.

[27] OGAKI MB ET AL. 2020. Diversity and bioprospecting of cultivable fungal assemblages in sediments of lakes in the Antarctic Peninsula. Fungal Biol 124: 601-611.

[28] REN J, XUE C, TIAN L, XU M, CHEN J, DENG Z, PROKSCH P & LIN W. 2009. Asperelines A-F, peptaibols from the marine-derived fungus Trichoderman asperellum. J Nat Prod 72: 1036-1044.

[29] RITCHIE NA. 2006. Frozen solid: recent archaeological work at Shackleton’s Cape Royd’s hut site (1907-1909), Ross Island, Ross Dependency, Antarctica. In: Paterson A & Casey M (Eds), Volume of Papers in Honour of Judy Birmingham, Australasian Historical Archaeology, p. 39.

[30] ROSA LH, DA SILVA TH, OGAKI MB, PINTO OHB, STECH M, CONVEY P, CARVALHO- SILVA M, ROSA CA & CâMARA PE. 2020b. DNA metabarcoding uncovers fungal diversity in soils of protected and non-protected areas on Deception Island, Antarctica. Sci Rep 10: 21986.

[31] ROSA LH, PINTO OHB, CONVEY P, CARVALHO-SILVA M, ROSA CA & CâMARA PEAS. 2020a. DNA metabarcoding to assess the diversity of airborne fungi present over Keller Peninsula, King George Island, Antarctica. Microb Ecol 82: 165-172.

[32] ROSA LH, PINTO OHB, ŠANTL-TEMKIV T, CONVEY P, CARVALHO-SILVA M, ROSA CA & CâMARA PE. 2020c. DNA metabarcoding of fungal diversity in air and snow of Livingston Island, South Shetland Islands, Antarctica. Sci Rep 10: 21793.

[33] ROSA LH, SOUSA JRP, DE MENEZES GCA, COSTA CL, CARVALHO-SILVA M CONVEY P & CâMARA PEAS. 2020d. Opportunistic fungi found in fairy rings are present on different moss species in the Antarctic Peninsula. Polar Biol 43: 587-596.

[34] ROSA LH, VAZ ABM, CALIGIORNE RB, CAMPOLINA S & ROSA CA. 2009. Endophytic fungi associated with the Antarctic Grass Deschampsia antarctica Desv. (Poaceae). Polar Biol 32: 161-167.

[35] ROSA LH, ZANI CL, CANTRELL CL, DUKE SO, VAN DIJCK P, DESIDERI A & ROSA CA. 2019. Fungi in Antarctica: diversity, ecology, effects of climate change, and bioprospection for bioactive compounds. In Rosa LH (Ed), Fungi of Antarctica, Springer, Cham, Switzerland, p. 1-17.

[36] SAMUELS GJ. 1996. Trichoderma: a review of biology and systematics of the genus. Mycol Res 100: 923-935.

[37] SOARES FC, DA ROSA LAS, JÓIA TC & PEÑA WLS. 2016. A (des) Construção da embriaguez em solos Antárticos. Comida, Cultura e Sociedade: Arqueologia da Alimentação no Mundo Moderno, 139-168.

[38] SOARES FC, DE AMORIM CL & PENA WLS. 2019. Um fio de fumaça nos mares do sul cachimbos de caulim e masculinidades nas Ilhas Shetland do Sul (séculos XVIII e XIX). Rev Arqueol 32: 129-159.

[39] SOARES FC & GARDIMAN GG. 2017. Mais uma dose: análise arqueobotânica do consumo de cerveja nas Shetland do Sul (Antártica). Rev Habitus 15: 273-299.

[40] STCHIGEL AM, JOSEP CANO, MAC CORMACK W & GUARRO J. 2001. Antarctomyces psychrotrophicus gen. et sp. nov., a new ascomycete from Antarctica. Mycol Res 105: 377-382.

[41] TAMURA K, PETERSON D, PETERSON N, STECHER G, NEI M & KUMAR S. 2011. MEGA5: molecular evolutionary genetics analysis using maximum likelihood, evolutionary distance, and maximum parsimony methods. Mol Biol Evol 28: 2731-2739.

[42] URZÌ C & KRUMBEIN WE. 1994. Microbiological impacts on the cultural heritage. In: KRUMBEIN WE et al. (Eds), Durability and Change: The Science, Responsibility, and Cost of Sustaining Cultural Heritage New York: J Wiley & Sons, New York, USA, p. 107-135.

[43] WHITE TJ, BRUNS TD & LEE SB. 1990. Amplification and direct sequencing of fungal ribosomal RNA genes for phylogenetics. In: Innis NA et al. (Eds), PCR protocols: a guide to methods and applications. Academic Press, San Diego, USA, p. 315-322.

[44] ZARANKIN A, HISSA S, SALERNO M, FRONER Y, RADICCHI G, ASSIS L & BATISTA A. 2011. Paisagens em branco: arqueologia e antropologia antárticas - avanços e desafios. Vestígios: Rev Lat-Amer Arqueol Hist 5: 9-52.

[45] ZARANKIN A & SENATORES M. 1996. Informe Campaña Arqueologica Antartica. Peninsula Byers, Isla Livingston, Shetland del Sur. Verano 1995/1996. Buenos Aires: Programa de Estudios Prehistoricos - CONICET.

Site	Coordinates	Artefact	Inventory code	Fieldwork year	Artefacts information	Storage temperature (°C)
PX-2	62°40’21.6”S; 60°55’45.9”W	Wood	2012.0888	2013	Half of barrel slap, 42 cm in diameter and 1.7 cm thick. On one of its faces, possibly the external one, are noted marks resulting from cut activities, which indicates the reuse of the parts for purposes other than which was initially manufactured. It was probably reused for food or animal processing	25
		Fabric	2012.0848	2013	Glove made of tricot with fibers of animal origin (wool). This piece integrates a set of items used as clothing, its fiber is elastic and insulating at low temperatures	10
X-1	62°68’51.8’’S; 60°85’34.0’’W	Wood	2014.1261	2014	Wood fragment that appears to be part of a whaling boat, due to its dimensions (length and width). The analyzed fragment has a blackened surface, possibly related to the action of fire (use as fire pit fuel)	25
Punta Varadero	62°36’49.6”S 61°04’8.06”W	Fabric/skin/soil	2011.0316	2012	Cluster of organic remains, composed of a mix of animal skin, remains of tissues, soil and micro bone fragments	10
Sealer 1	62°36’30”S; 61°02’07”W	Whale bone	2017.1395	2017	Whale vertebrae used as internal furniture in the sealer hut, especially a chair or improvised tables. This has a blackish color that suggests its proximity to the fire-pit	10

Sample	Storage temperature (°C)	isolation temperature (°C)	N° of fungal isolates	UFMGCB^a	Top BLAST search results (GenBank accession number)	Query cover (%)	Identity (%)	N° of bp analyzed	Proposed taxa (GenBank acc. n°)
Wood Figure 2, (a,c)	25	25	3	14060	Penicillium rubens (NR111815)^b	100	100	434	Penicillium sp. 1 (MZ318091)^d
			3	14217	Talaromyces domesticus (MH793055)^b Talaromyces domesticus (MH793118)^c	100 100	100 99.7	373 661	Talaromyces domesticus (MZ318092)^d, (MZ223864)e
Fabric Figure 2, (d)	10	10	2	14205	Penicillium repensicola (NR153209)^b	100	100	385	Penicillium sp. 2 (MZ318093)^d
			1	14203	Antarctomyces psychrotrophicus (NR164292)^b	100	100	721	Antarctomyces sp. (MZ318094)^d
			2	14202	Mortierella zonata (JX975983)^b	99	96.5	579	Mortierella sp. (MZ318095)^d
Fabric/skin/soil Figure 2, (e)	10	10	2	14207	Trichoderma gamsii (NR131317)^b	100	100	317	Trichoderma sp. 1 (MZ318096)^d
			2	14215	Trichoderma atroviride (AF456917)^b	100	100	375	Trichoderma sp. 2 (MZ318097)^d
Whale bone Figure 2, (b)	10	10	2	14208	Penicillium caseifulvum (NR163685)^b	100	100	355	Penicillium sp. 3 (MZ318098)^d
			3	14200	Linnemannia hyalina (NR163542)^b	100	94.5	503	Linnemannia sp. (MZ318099)^d