M8060 40 2010 Y 8060 40 2010 C 8060 40 2010 B 8060 40 2010 M8060 40 2010 Y 8060 40 2010 C 8060 40 2010 B 8060 40 2010 M8060 40 2010 Y 8060 40 2010 C 8060 40 2010 B 8060 40 2010 B U L G A R IA N A N T A R C T IC R E S E A R C H (cid:139) V O L U M E 4 M8060 40 2010 Y 8060 40 2010 C 8060 40 2010 B 8060 40 2010 M8060 40 2010 Y 8060 40 2010 C 8060 40 2010 B 8060 40 2010 M8060 40 2010 Y 8060 40 2010 C 8060 40 2010 B 8060 40 2010 BAR4 Page i BULGARIAN ANTARCTIC RESEARCH Life Sciences Vol. 4 BAR4 Page ii This page intentionally left blank BAR4 Page iii Bulgarian Bulgarian Antarctic Institute Academy of Sciences BULGARIAN ANTARCTIC RESEARCH Life Sciences Volume 4 Edited by Acad. V. Golemansky & Dr. N. Chipev Sofia - Moscow 2004 BAR4 Page iv Bulgarian Academy of Sciences © PENSOFT Publishers ISBN 954-642-219-3 (Vol. 4) First published 2004 All rights reserved All rights reserved. No part of this publication may be reproduced, stored in a retrieval system or transmitted in any form by any means, electronic, mechanical, photo copying, recording or otherwise, without the prior written permission of the copyright owner. Pensoft Publishers, Geo Milev str., No. 13a, 1111 Sofia, Bulgaria E-mail: [email protected], www.pensoft.net Printed in Bulgaria, December 2004 BAR4 Page v Contents SOIL CHARACTERISTICS AND MICROBIAL ABUNDANCE OF MOSS AND COASTAL HABITATS OF LIVINGSTON ISLAND – ANTARCTICA A. Kenarova, V. Bogoev..................................................................................................................1 LIPID COMPOSITION AND β-GLUCOSIDASE PRODUCTION FROM CRYPTOCOCCUS VISHNIACII AL 4 K. Pavlova, M. Zlatanov, G. Angelova, I. Savova.......................................................................9 KERATINASE PRODUCTION OF THERMOPHILIC ACTINOMYCETES SPECIES FROM ANTRACTICA A. Gushterova, M. Noustorova, K. Pavlova.............................................................................23 ISOLATION AND TAXONOMIC STUDY OF ANTARCTIC YEASTS FROM LIVINGSTON ISLAND FOR EXOPOLYSACCHARIDE-PRODUCING K. Pavlova, A. Gushterova, I. Savova, M. Nustorova..............................................................27 BIOCHEMICAL CHARACTERISTIC OF ANTARCTIC YEASTS K. Pavlova, M. Zlatanov, L. Koleva, I. Pishtiyski......................................................................35 EFFECT OF TEMPERATURE AND SODIUM CHLORIDE ON THE BIOMASS AND FATTY ACIDS COMPOSITION OF ANTARCTIC YEAST STRAIN SPOROBOLOMYCES ROSEUS AL 8 L. Koleva, K. Pavlova, M. Zlatanov............................................................................................47 ALKALOIDS FROM THE ANTARCTIC STRAIN MICROBISPORA AERATA SUBSP. NOV. IMBAS-11A. ISOLATION, SEPARATION AND PHYSICO-CHEMICAL PROPERTIES V. Ivanova, U. Graefe, R. Schlegel, A. Gusterova, K. Aleksieva, M. Kolarova, R. Tzvetkova...........................................................................................................55 ARRHENIA RETIRUGA (BULL.: FR.) REDHEAD VAR. ANTARCTICA HORAC – ONE AGARICAL FUNGUS FROM LIVINGSTON ISLAND, SOUTH SHETLANDS (THE ANTARCTIC) M. Gyosheva and R. Metcheva.....................................................................................................65 DISTRIBUTION OF FRESHWATER ALGAE ON LIVINGSTON ISLAND, SOUTH SHETLANDS ISLANDS, ANTARCTICA .II. (CYANOPRO- KARYOTA) D. Temniskova-Topalova, R. Zidarova.......................................................................................69 BAR4 Page vi vi CONTENTS ADDITIONAL DATA AND SUMMARIZED CHECK-LIST ON THE RHIZOPODS (RHIZOPODA: AMOEBIDA & TESTACEA) FROM LIVINGSTON ISLAND, SOUTH SHETLANDS, THE ANTARCTIC V. Golemansky, M. Todorov........................................................................................................83 REVIEW ON THE FREE-LIVING COPEPODS (CRUSTACEA) FROM THE REGION OF THE BULGARIAN ANTARCTIC BASE, LIVINGSTON ISLAND I. Pandourski, A. Apostolov........................................................................................................95 HEAVY METALS AND TOXIC ELEMENTS CONTENT IN GENTOO PENGUINS (PYGOSCELIS PAPUA) FEATHERS DURING MOULT R. Metcheva, L. Yurukova...........................................................................................................101 BLOOD CHEMISTRY STUDIES AND DIFFERENTIAL COUNTING OF LEUCOCYTES IN GENTOO PENGUINS (PYGOSCELIS PAPUA) IN RELATION OF MOULTING AND NON-MOULTING STAGES E. Trakijska, K. Stojanova, R. Metcheva...................................................................................107 GENTOO PENGUIN COLONY ESTIMATES USING DIGITAL PHOTO- GRAPHY R. Metcheva, P. Zehtindjev, Y. Yankov......................................................................................115 COMPARATIVE STUDIES ON THE CONTENTS OF CHEMICAL ELE- MENTS IN SOIL COVER FROM LIVINGSTON ISLAND, ANTARCTICA M. Sokolovska, J. Bech................................................................................................................123 BAR4 Page 1 © PSEONILS OCFHTA RPAuCbTliEsRhIeSrTsICS AND MICROBIAL ABUNDANCE OF MOSS AND COBAuSlgTaArLia nH AABnItTaArcTtSic . .R.esearc1h Sofia – Moscow Life Sciences, vol. 4: 1-8, 2004 Soil characteristics and microbial abundance of moss and coastal habitats of Livingston Island – Antarctica A. KENAROVA, V. BOGOEV Department of Ecology and Nature Protection, Faculty of Biology – St. Kliment Ohridsky University of Sofia, 8 Dragan Tzankov St., 1164 Sofia, Bulgaria ABSTRACT Soil samples from three different types of habitats (moss, moss- ornithogenic and coastal- ornithogenic) were studied according to their nutrient and microbiological charac- teristics. The soils tested are relatively well stocked with organic matter but poor in inorganic nitrogen and phosphorus. The concentration of organic matter is an individual characteris- tic of the samples but not of the soil groups. The stock of nitrogen and phosphorus is the chemical characteristic of the soil groups which differ them each other significantly. The bioligical differences of soil groups are given by their microbiological characteris- tics, especially the fungal and bacterial biomass as well as the abundance of saprotrophic bacteria. The abundance of oligotrophic bacteria cannot be assumed as a biological char- acteristic of soil groups because of the statistically unsignificant difference in the inter group variance of this parameter. KEY WORDS Antarctica, Livingston island, soil habitats, soil microorganisms. INTRODUCTION The extreme conditions of Antarctica determine the specific character of soil mi- crobiota, inhabiting the continental, coastal or island part of the Continent. The seasonal changes of the climate influence much more the biota of the island and coastal part than the inner continental one where the soil annualy is freezed and ice covered. *Grant B. A. 801 / 1998 of National Fund for Scientific Researches of Bulgaria BAR4 Page 2 2 A. KENAROVA, V. BOGOEV It is the point of freeze- thaw transitions rather than the temperature itself which is critical for the onset of microbial activity. Such transitions lead not only to existence of free water in the environment but also to release of organic substances by the microorganisms, cryptogamic flora and invertebrates (Collins et al. 1975; Block 1984; Smith 1984). The turn between winter inactive condition to one of summer microbi- al activity can be fulfilled within the limits of a day (Wynn-Williams 1980). At the coastal and island part of Antarctica two basic types of habitats have been formed in respect of the higher concentrations of organic matter in soil – commu- nities of mosses in the damper parts and ornithogenic coastal soils. The rate of organic decomposition is a factor for the existence of the moss habitat itself (Wynn-Williams 1980, 1988). The balance between growth and decom- posing of moss determines whether or not on a certain place a peat field or moss covering will be formed (Davis 1986). In the peat-moss communities there are a great number of heterotrophic and autotrophic microorganisms (Christie 1987; Davis 1981; Burn 1984; Lister et al. 1987). The basic source of nitrogen, phosphates and nutrients on the cold oligotrophic soils is the guano secreted by the penguins. Published data show that despite the great number of bacteria, less than 8% of the populations are metabolically active even during summer (Ramsy 1983; Gushterova 1999). The bacteria from the alimentary tract of penguins probably cannot adapt to low temperatures of the environment and/or are inhibited by different antibiotic substances like the acrylic acid secreted from some sea phytoplankton, consumed by Euphansia superba, which serves as food for the penguins (Sieburth 1969). The subject of this study is to determine the differences between abiotic and biotic characteristics of the moss, moss-ornithogenic and ornithogenic soils from the Livingston Island. MATERIALS AND METHODS Soil samples from Livingston Island were taken in January 2002 from the Bulgar- ian Antarctic expedition. They were dried in room temperature, then sifted and kept in sterile paper bags at 4°C. The samples were divided into three groups according to the type of habitats they were taken from – moss (1), moss- ornitogenic (2) and coastal- ornitogenic (3). The pH was measured by pH-meter in water extract – 1g soil:25ml distillated water. The amount of organic matter was determined after Tyurin’s method based on oxidation of organic matter by potassium dichromate (Kaurichev 1980). The concentration of phosphoates and inorganic nitrogen (ammonium and ni- trate) were determined in a way recommended in “Methods of soil analyses..” (Bak- er and Norman 1982; Keeney and Nelson 1982). BAR4 Page 3 SOIL CHARACTERISTICS AND MICROBIAL ABUNDANCE OF MOSS AND COASTAL HABITATS ... 3 The amount of fungal and bacterial biomass was calculated after microscopic measurement of fungal mycelium length (light microscopy) and bacterial number counting (epiflourescent microscopy); from the average values of measured param- eters the amount of fungal and bacterial biomass was calculated (Zviagincev and Zaiceva 1979; Zviagincev at al. 1978). Abundance of heterotrophic and oligotrophic bacteria was counted on selective media- heterotrophs on a tenfold diluted nutrient agar and oligotrophs on a salt agar amended with 10% soil extract. After inoculation the petri dishes were cultivated at 11-12°C for 7-10 days. Statistical analyses were processed according to the inner- and inter soil groups’ variations of microbiological and chemical characteristics (Moroney 1969). RESULTS AND DISCUSSION The soils from the three habitats (moss, moss-ornithogenic and coastal-ornitho- genic) are poor in inorganic nitrogen and phosphorus and comparatively well pro- vided with organic matter (Tabl.1.). Similar data concerning the chemistry of soils from Livingston Island were also published by Nustorova et al. (2002). The reason for the low quantities of inorganic nitrogen and phosphorus in the soil samples, compared to the existing organic matter, is most likely the low microbial activity, inhibited from the unfavourable conditions of the environment. Of the three soils groups investigated, the best supplied with biogenic elements are moss-ornithogenic soils and these conditions of the specific environment favor the better metabolic activity of microorganisms. This question is the subject of a thorough discussion by many authors (Tearle 1987; Wynn-Williams 1980, 1982; Pugh et al. 1982; Davis 1986; Christie 1987). The consideration of statistical analysis find out the existence of difference be- tween inter- and inner soil group variability of nitrogen, phosphorus and pH values (Table 2). Although their common characteristic of low level of the inorganic nitro- gen and phosphorus reserves, soils from the different habitats have group identity in respect of the average levels of these parameters. The existing inner-group variation Table 1. Physic- chemical characteristics of the soil groups. Soil group pH organic NO-N NH-N HPO -P 3 4 4 of habitats matter % mg kg-1 mg kg-1 mg kg-1 moss 6.27 5.22 2.4 16 20 moss-ornitogenic 6.56 12.16 6.4 48 32 coastal-ornitogenic 6.92 9.08 1.7 18 24