Subterranean Biology 45: 53—74 (2023)

doi: 10.3897/subtbiol.45.97 105 RESEARCH ARTICLE SW, DUerranean
O8Y misses

https://subtbiol.pensoft.net

First data on testate amoebae associated
with the endemic cave bivalve Congeria jalzici
Morton & Bilandzija, 2013 with a description

of Psammonobiotus dinarica sp. nov.

Najla Bakovi¢'??, Ferry Siemensma’*, Sanja Puljas°,
Robert Bakovié!*, Roman Ozimec!, Ana Ostoji¢®, Zrinka Mesi¢®
J

| ADIPA — Society for Research and Conservation of Croatian Natural Diversity, Zagreb, Croatia 2. Croatian
Biospeleological Society, Zagreb, Croatia 3 DVOKUT-ECRO Ltd, Zagreb, Croatia 4 Julianaweg 10, 1241VW
Kortenhoef, Netherlands 5 Faculty of Science, University of Split, Split, Croatia 6 Oikon Ltd. — Institute of
Applied Ecology, Zagreb, Croatia

Corresponding author: Najla Bakovi¢ (najla.bakovic@gmail.com)

Academiceditor:R. Mayén-Estrada | Received 3 November 2022 | Accepted 22 January 2023 | Published 21 February2023
https://zoobank. org/3 CEBADA2-26F6-486 1-9ABF-746EFB65C85A

Citation: Bakovi¢ N, Siemensma F, Puljas S$, Bakovi¢ R, Ozimec R, Ostoji¢ A, Mesi¢ Z (2023) First data on testate
amoebae associated with the endemic cave bivalve Congeria jalzici Morton & Bilandzija, 2013 with a description of

Psammonobiotus dinarica sp. nov. Subterranean Biology 45: 53-74. https://doi.org/10.3897/subtbiol.45.97105

Abstract

Testate amoebae are phylogenetically a very diverse group of eukaryotic microorganisms. They can be
found in marine and freshwater habitats and in soil. Some of these single-celled organisms inhabit both
surface and cave habitats, but their diversity in caves has barely been explored. Recent studies in the
Dinaric region imply that testate amoebae in caves show a high diversity. The aim of this study was to
identify the alpha diversity of testate amoebae in the Lika region (Dinaric karst, Croatia) and to compare
the habitats of different caves based on testate amoebae assemblages. In eight caves we found more than
40 testate amoebae taxa, including a new testate amoeba species, Psammonobiotus dinarica sp. nov. The
greatest diversity of testate amoebae was found in Markov ponor (27 taxa). The Bray-Curtis Similarity
Index showed that testate amoebae assemblages in caves inhabited by the endemic and endangered cave
bivalve Congeria jalzici (Markov ponor, Dankov ponor and Drazice ponor) differ from caves not inhabited
by this species. This differentiation is attributed to the impact of the sinking Lika river, which occasionally
completely submerges these caves, creating specific habitats for eukaryotic microorganisms. This study
contributes to our understanding of the diversity, biogeography and ecology of testate amoebae in caves,

as well as providing further insight into the conditions that sustain populations of C. jalzici.

Copyright Najla Bakovic et al. This is an open access article distributed under the terms of the Creative Commons Attribution License (CC
BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.

54 Najla Bakovié et al. / Subterranean Biology 45: 53-74 (2023)

Keywords
cave flooding, cave heterogeneity, cave protists, Centropyxis, Difflugia, hygropetric, Markov ponor,
Microchlamys patella, psammobiotic testate amoebae, sinkholes, unicellular cave organisms

Introduction

The Dinaric karst of the Western Balkans is world’s most important subterranean
biodiversity hotspot and is classified as a unique and rare ecosystem with numerous
endemic species (Sket et al. 2004; Culver et al. 2006; Sket 2012). Biodiversity unique-
ness has been recognized by a subterranean community that reflect adaptations to spe-
cific conditions and past intense geologic events that drove speciation and migration
(Culver and Sket 2000).

Among the representatives of stigobionts as aquatic species in Europe, only
one genus of bivalves is represented in caves. The Tertiary relict genus Congeria
currently survives as three distinct species, namely Congeria kusceri Bole, 1962,
C. mulaomerovici Morton & Bilandzija, 2013, and C. jalzici Morton & Bilandzija,
2013, with a highly fragmented distribution (Bilandzija et al. 2014; Jovanovic
Glavas et al. 2017). All three species occur in only 15 caves in the Dinaric karst
region (Jalzi¢ 1998, 2001; Bilandzija et al. 2014; Jovanovi¢ Glavas et al. 2017),
but the rapid decline or disappearance of Congeria populations observed in recent
decades underscores that much more needs to be done for the species conservation
(BilandZzija et al. 2021).

Among the many ecological traits of Congeria (Morton and Puljas 2013; Puljas
et al. 2014), the most interesting is adaptation to extreme habitat variations (pres-
ence of water and temperatures). Sinkholes with Congeria in the Lika region are
completely or partially flooded only during high water events. ‘These flooding events
are partly controlled by the operation of the hydropower system on the Lika River.
When these sinkholes are flooded, they provide an optimal habitat for Congeria, as
it allows them to feed and reproduce. After the flooding of the Lika River waters
subside, the slow decline of the water level in the sinkholes starts. Habitats that were
once running water slowly turn into lake habitats and eventually the water is com-
pletely depleted. After that, the water on Congeria habitats is limited to seeping wa-
ter that comes from the epikarst layer above the cave and wet walls. When Congeria
habitat is converted to non-aquatic habitat, the most extreme conditions for the
species begin. The importance of this habitat is usually discussed in the literature as
an extreme part of the life cycle of Congeria (Jovanovi¢ Glavas et al. 2017; Bilandzija
et al. 2021), but there are no further data on the habitat itself. There are many active
sinkholes in the Dinaric karst region and many caves with constantly flooded chan-
nels, but the distribution of Congeria species is limited to just a few localities. This
implies that caves with Congeria hold some traits that are unique and differentiate
them from other caves.

Testate amoebae associated with the endemic cave bivalve Congeria jalzici 55

Despite the fact that Congeria species are under high threats both due to various
human interventions (e.g. hydrotechnical projects) and climate change (Bilandzija
et al. 2021), very little data is available on this species. Previous studies of Congeria
spp. have included some data on species biology and population structure (Jalzic
1998, 2001; Morton et al. 1998; Morton and Puljas 2013; Bilandzija et al. 2014;
Puljas et al. 2014; Jovanovié Glavas et al. 2017), evolutionary biology (Stepien et
al. 2001; Bilandzija et al. 2014) and viruses in Congeria species (Scapolatiello et al.
2022). Relationships of Congeria and unicellular eukaryotic microorganisms (pro-
tists) have never been investigated. Only data on protists from caves with Congeria
are findings of algae in the aphotic zone of Markov ponor, Dankov ponor and
Drazice ponor, noted by Bakovié et al. (2022b). Their presence was attributed to
flood waters of the Lika River. When discussing cave protists in the context of
Congeria, we can only make some hypotheteses based on the general ecology of
these groups of organisms. Some cave protists could compete with Congeria for
food (e.g., organic particles, bacteria) (Hausmann et al. 2003) or even represent a
compatible food source for Congeria (very small eukaryots) (Morton et al. 1998;
Gosling 2003). During the high water periods (when Congeria colonies are sub-
merged) metabolic products of Congeria (urine, faeces) may alter the microenvi-
ronment around them, which may affect the composition of microorganisms, but
it is expected that this impact will diminish in periods of drought as Congeria is in
a dormant stage. The most distinctive common trait of cave protists and Congeria
are habitats they share. For this reason the focus of this paper will be on testate
amoebae assemblages present in cave habitats with Congeria, as opposed to other
caves in the Lika region.

Existing data on cave protists in general are very limited. Caves are inhabited by
mostly cosmopolitan protists described from epigean habitats (Gittleson and Hoo-
ver 1969, 1970; Golemansky and Bonnet 1994). Nevertheless, several species and
forms have been described from caves (Chibisova 1967; Delhez and Chardez 1970;
Walochnik and Mulec 2009; Bakovi¢ et al. 2019) and cave entrances (Main 2003;
Bhatt and Karthick 2020; Soler-Zamora et al. 2021). Protists are the trophic link
between metazoans and prokaryotic organisms (archaea and bacteria), and thus they
are important members of cave ecosystems. Considering their small size, short life
cycle, quick response to environmental changes, numerous communities and diverse
ecological niches they fill (Hausmann et al. 2003), protists are very compatible as
indicator organisms (Foissner and Berger 1996; Bellinger and Siegee 2015). Till now,
only ciliates have been investigated in the context of environmental indication in
caves by Italian researchers (Coppellotti and Guidolin 1999). Bakovié et al. (2022a)
showed that protist assemblages can be used for identification of habitat diversity in
caves. Among protist from caves, great potential for researching cave ecology can be
attributed to testate amoebae. Testate amoebae are very diverse in caves in comparison
with other protists (Bakovi¢ et al. 2019) and the species composition is determined by
the specific habitats (Golemansky and Bonnet 1994) and cave heterogeneity (Mazei

56 Najla Bakovié et al. / Subterranean Biology 45: 53-74 (2023)

et al. 2012). They have been recognized and tested as valuable indicators of environ-
mental changes in many surface habitats such as peatlands, soil and aquatic habitats
(e.g. Bobrov 2005; Qin et al. 2016; Carballeira and Pontevedra-Pombal 2021). Data
on protists in the wider area of the Lika region are scarce. The only data on testate
amoebae including caves from this research is that the Cakovac cave, the Horvatova
cave and the Prazina cave are inhabited by the recently described species Centropyxis
bipilata (Bakovié et al. 2019).

The goal of this study was to identify the diversity of testate amoebae present in se-
lected caves of the Lika region and to determine whether there are differences between
testate amoebae assemblages from caves inhabited by the endemic bivalve C. jalzici and
other caves not inhabited by this species. This research brings the first data on hetero-
trophic protists associated with C. jalzici and the description of a new testate amoeba
species for science.

Research location and hydrological settings

All studied caves are presented in Table 1 with cave name and location, sampling date,
sampled habitat of testate amoebae and sample designation.

Markov ponor, Dankov ponor and Drazice ponor are sinkhole type caves formed
in deposits of Jurasic limestones and dolomites (J,'”, J,, J,*). They are located on the
NE edge of the Lipovo polje (karst field) (elevation approx. 451 m m.a.s.l.) (Fig. 1).
These caves are natural sinkholes of the Lika river, but the flooding regime is modified
after the building of two artificial dams (the Seliste and the dam of the Senj Hydro
Power Plant). Water is released in sinkholes just during very high waters. Markov
ponor is very complex, multilevel objects, while Dankov ponor and Drazice ponor
are less complex objects. Prazina pecina, Buklina, Pecina u Cakovcu and Horvatova
spilja are formed in deposits of Eocen-Oligocen breccias-conglomerates (E, Ol) in
the elevated area of Mlakva and Mlakvina greda (elevation 521-595m m.a.s.l.), while
Samograd is formed in limestone deposits of the Upper Cretaceous, Cenoman and
Turone in the Grabovaca area (670 m m.a.s.l.) (Fig. 1). Horvatova spilja and Pecina
u Cakovcu are multichannel caves. The Prazina pe¢ina and Buklina caves are of a
simple morphology. In the lower levels of Pecina u Cakovcu a cave lake is present.
Horvatova Spilja is located in the artificial dam of the Senj Hydro Power Plant and
it is partially and occasionally flooded. In Prazina pe¢ina and Buklina only seeping
and dripping water is present. Total cave channel lengths are: Dankov ponor=250 m,
Drazice ponor=approx. 140 m, Markov ponor=2557 m, Prazina pecina=27 m, Buk-
lina=20 m, Pecina u Cakovcu=267 m, Samograd=345 m and Horvatova Sspilja=500
m. In the wider area of these caves building of new hydropower accumulation is
planned in the future. It will completely flood the Pe¢ina u Cakovcu and further
modify the hydrological regime of Markov ponor, Dankov ponor and Drazice ponor
by decreasing flooding frequency and quantities of water flooding these caves (Stroj

2010; Elektroprojekt Ltd. 2017).

Testate amoebae associated with the endemic cave bivalve Congeria jalzici 57

\ Sumeéica-Seliste
Tunnel

Lika River

DAN

BUK
|_|
C)
PRA
Bakovac River
Krus¢ica
Artificial Lake
Legend 4
. Pe C]
A Caves with Congeria jalzici SAM
Caves without Congeria jalzici
0 1 2 3 km
e@ Artificial dam
es
~

Figure |. Research location and hydrographic map showing the main permanent and temporary water
bodies and the hydrotechnical tunnel (DAN — Dankov ponor, DRA — Drazice ponor, MAR — Markov
ponor, BUK — Buklina, PRA — Prazina pecina, CAK ~— Peéina u Cakovcu, HOR — Horvatova pecina,
SAM - Samograd).

Methodology

Description of studied habitats

Caves with Congeria jalzici (Markov ponor, Dankov ponor, Drazice ponor) are season-
ally completely or partially flooded by the Lika river that sinks into these caves. Thus,
habitats inside caves are transforming depending on the hydrological regime. These
caves were studied during periods of low waters, when the caves were accessible to
speleobiologists. Studied habitats were: a small cave lake with submerged colonies of
C. jalzici, cave walls with attached individuals of C. jalzici, cave walls without indi-
viduals of C. jalzici and small cave pools unrelated to C. jalgici. The water present in
a small cave lake with submerged colonies of C’ jalzici is a remnant of water imported
to the cave by the Lika river during the flood events. Organic debris and small waste
(plastic etc.) fragments were present on the surface of the lake. The water level in these
lakes gradually drops during the dry season, leaving the colonies of C. jalzici out of
the water. Habitats, with attached C. jalzici, outside the water column are transitional
habitats (hygropetric) and wet walls. Transitional habitats (hygropetric) are very thin
and consist of slowly seeping water that flows over the surface of the cave wall and at-
tached individuals of C. jalzici. Although there is no visible seeping water on the wet

58 Najla Bakovié et al. / Subterranean Biology 45: 53-74 (2023)

walls, they are still permanently wet due to the high air humidity inside the cave. There
are also several locations with small pools in the caves. ‘The distinction between transi-
tional habitats and wet walls is not always clear. ‘The investigated sinter and clay pools
in these caves are relatively small (a few centimeters wide and deep).

The investigated habitats in the caves without C: jalgici (Prazina pecina, Buklina,
Pedina u Cakovcu, Horvatova Spilja and Samograd) were not flooded by exogenous riv-
ers. These researched habitats depended on seeping and dripping water. In most habitats
of these caves traces of old bats guano are present, which is detectable in microscopical
samples by the presence of small quantities of insects leftovers. Only in samples BUK_th
and SAM_sp significant quantities of bats guano were found, while sample HOR_bg
consisted of bats guano deposits (Table 1). Transitional habitats (hygropetric) in these
caves were characterized by a very thin layer of seeping water that flows on the surface of
the cave walls. ‘The sinter pools in Prazina pecina and Samograd were 30 cm wide and up
to 15 cm deep, while the sinter pools in Pecina u Cakovcu were several cm wide and deep.

Table |. Collected samples.

No. Cave name and location Sampling Sampled habitat of testate amoebae Sample
date designation
Caves with Congeria jalzici
1 Dankov ponor, Lipovo polje, CRO 08/2016* — Transitional habitat with C. jalzici DAN_th
2 Dankov ponor, Lipovo polje, CRO 08/2016 Ex situ swabs of shells of living C. jalzici DAN_esw
3 Drazice ponor, Lipovo polje, CRO 08/2016* Transitional habitat with C. jalzici DRA_th
4 Drazice ponor, Lipovo polje, CRO 11/2018 Transitional habitat DRA_th2
5 Drazice ponor, Lipovo polje, CRO 11/2018 Transitional habitat DRA_th3
6 Drazice ponor, Lipovo polje, CRO 11/2018 In situ swabs of shells of living C. jalzici DRA_isw
7 Drazice ponor, Lipovo polje, CRO 11/2018 Ex situ swabs of shells of living C. jalzici DDRA_esw
8 = Markov ponor, Lipovo polje, CRO 09/2016* — Transitional habitat with C. jalzici MAR_th1
9 Markov ponor, Lipovo polje, CRO 09/2016* — Transitional habitat with C. jalzici MAR_th2
10 Markov ponor, Lipovo polje, CRO 10/2016 Plankton from cave lake (65 um mesh) MAR_plal
11 Markov ponor, Lipovo polje, CRO 10/2016 Plankton from cave lake (120 um mesh) MAR_pla2
12. Markov ponor, Lipovo polje, CRO 10/2016 Floating debris from cave lake MAR_deb
13. Markov ponor, Lipovo polje, CRO 11/2021 Transitional habitat MAR _th1
14 Markov ponor, Lipovo polje, CRO 11/2021 Transitional habitat MAR_th2
15. Markov ponor, Lipovo polje, CRO 11/2021 Sinter pool filled with water MAR_sin
16 Markov ponor, Lipovo polje, CRO 11/2021 Clay pool MAR _clp
Caves without Congeria jalzici
17 Buklina (syn. Spilja u Poljani), Poljana, CRO 08/2016* Transitional habitat BUK_th
18 Horvatova Spilja, HPP Sklope, Mlakva, CRO 08/2016* Bats guano deposits HOR_bg
19 Horvatova Spilja, HPP Sklope, Mlakva, CRO 08/2016* Transitional habitat HOR_th
20 Peéina u Cakovcu, Bobidi, Mlakva, CRO 08/2016* Transitional habitat CAK_thl
21 Peéina u Cakovcu, Bobi¢i, Mlakva, CRO 08/2016* Terrestrial sediment CAK_terr
22 ~~ Peéina u Cakovcu, Bobiéi, Mlakva, CRO 09/2016* Transitional habitat CAK_th2
23 -Peéina u Cakovcu, Bobi¢i, Mlakva, CRO 09/2016* Sinter pool filled with water CAK_sp
24 Prazina pecina, Poljana, Mlakva, CRO 08/2016* Transitional habitat PRA th
25 Prazina pecina, Poljana, Mlakva, CRO 08/2016* Sinter pool filled with water PRA_ sp
26 Samograd, Grabovaéa, Perusi¢, CRO 10/2016* Transitional habitat SAM_th
27. Samograd, Grabovaéa, Perusi¢, CRO 10/2016* Sinter pool filled with water SAM_sp

Samples marked with asterisk (*) were used for a descriptive statistics; other samples were used exclusively for the de-
scription of alpha diversity of testate amoebae.

Testate amoebae associated with the endemic cave bivalve Congeria jalzici 59

Sampling

The samples from Markov ponor (MAR_th1, MAR_th2), Dankov ponor (DAN_th)
and Drazice ponor (DRA_th) (Table 1) were collected by gently scrubbing with a plas-
tic brush the surfaces of shells of living Congeria jalzici and the transitional habitats
on which they were attached. The brush was then washed in a plastic container filled
with 40 ml of tap water. The process was repeated till the water became muddied.
Selected samples from Markov ponor (MAR_thl1, MAR_th2, MAR sin, MAR _clp)
and Drazice ponor (DRA_th2, DRA_th3), and all samples from the caves Prazina
pecina, Pecina u Cakovcu, Horvatova spilja and Samograd (Table 1) were collected by
using the methodology presented by Bakovi¢ et al. (2019).

Plankton samples from Markov ponor (MAR_plal, MAR_pla2) were collected
using plankton nets (65 um and 120 um mesh size) and placed into plastic contain-
ers. Floating debris from the cave lake (MAR_deb) was handpicked and placed into a
plastic container filled with lake water (Table 1).

Samples of protists living iz situ on the outer shells of C. jalzici (DRA_isw) were
collected by gently scrubbing with a plastic brush exclusively on the surfaces of shells
of living C. jalzici on transitional habitats. The brush wa then washed in a plastic con-
tainer filled with 40 ml of tap water. The process was repeated until the water became
cloudy. Ex situ samples of protists living on the outer shells of C. jalzici (DRA_esw,
DAN_esw) were scrubbed gently with a microscope cover slip (Table 1). Scrubbed
material was transferred directly to a microscope slide. One drop of water was added to
the microscope slide before the examination.

Transport to the lab, maintaining the temperature, examination

Samples were transported to the laboratory within several hours after the sampling and
stored at a temperature of 4-8 °C and analyzed within 48h from the time of the collec-
tion. Exceptions were selected samples from Markov ponor (MAR_plal, MAR_pla2,
MAR_deb) (Table 1) which were stored at room temperature and examined within a
72 hour time period from the time of collection.

Triplets of 0.2 ml from each sample (total of 0.6 ml) were examined using a Carl Zeiss
Axiostar microscope with 100, 400 and 1000 times magnification. For additional spe-
cies examination a Zeiss Axioscop 40 FL and an Olympus BX51 microscope with Phase
Contrast and Differential Interference Contrast (DIC) were used. A Nikon Diaphot
inverted microscope was used for examining samples and isolating specimens. Adobe
Photoshop and ToupView software were used for image processing and measurements.
All testate amoebae were identified to the lowest possible level. Species were identified by
using the following literature to begin with: Golemansky and Todorov (2004), Mazei and
Tsyganov (2006), Nicholls (2005), Ogden and Hedley (1980), Siemensma (2021) and
Todorov and Bankov (2019). An abundance of testate amoebae is noted only for samples
no. 1-2, 5-6, 14~24. Counted were all individuals in the examined volume (0.6 ml).
Based on the number obtained, it was estimated (mathematical calculation) how many
individuals would be in 1 ml. Since literature data on testate amoebae abundance in caves

60 Najla Bakovié et al. / Subterranean Biology 45: 53-74 (2023)

are lacking, available data from this research were used to determine ranges (low/high
abundance). Samples used only for the studding testate amoebae diversity were intensive-
ly examined in search of testate amoebae tests (> than 0.6 ml of sample was examined).

Data analyses

Descriptive statistics (Bray-Curtis similarity, Shannon diversity index and Pielou’s
evenness index) was done in Primer 6 (PRIMER-e Ltd) on selected samples collected
in 2016 (samples no. 1-2, 5-6, 14-24) which represented comparable data. Other
samples (3, 4, 7, 8,9, 10, 11, 12, 13) were used only for the contribution to knowledge
on testate amoebae diversity.

Results

Taxa diversity

Testate amoebae were found in 23 samples (85.1%). Exceptions were the samples of
the cave lake plankton (MAR_plal, MAR_pla2) and in ex situ swabs from the shells of
C. jalzici (DAN_esw, DRA_esw) that did not reveal any testate amoebae. Over forty
testate amoebae taxa were distinguished (Table 2, Plates 1-3). Among them, 33 taxa
have been identified to the species level, while others have been identified to the genus
level. Several taxa were identified just as testate amoebae due to the small number of ob-
served individuals that prevented accurate identification. Particularly diverse were taxa
of the genera Centropyxis and Diffiugia. The highest diversity of taxa (27) was found in
Markov ponor. Among the taxa found during this research, one new species for science
was identified and further described in this research — Psammonobiotus dinarica sp. nov.

Taxonomic description

Phylum: Cercozoa Cavalier-Smith 1998, emend. Ad] et al. 2005; emend. Cavalier-
Smith 2018

Class: Thecofilosea Cavalier-Smith 2003, emend. Cavalier-Smith 2011

Family: Incertae sedis Psammonobiotidae Golemansky 1974, emend. Meisterfeld
2002

Genus Psammonobiotus Golemansky, 1967

Psammonobiotus dinarica Bakovi¢ & Siemensma, sp. nov.
https://zoobank.org/89057 128-7C93-434D-BA9E-AOCF8F4E7 FAB
Plates 2K, 3A—E

Diagnosis. Shell is bilaterally symmetrical, in dorsal and ventral views spherical to
ovoid in outline and in lateral view compressed with a length/height ratio of about
2.3. A funnel-shaped collar extends from a kidney-shaped oral aperture. In lateral view,

Testate amoebae associated with the endemic cave bivalve Congeria jalzici 61

Plate |. A Cyclopyxis kahli B Difflugia cf pristis C Pseudodifflugia gracilis D Centropyxis aerophila E Centropyxis
constricta F Euglypha tuberculata G Cyphoderia laevis WH, Microchlamys patella. Scale bars: 20 um.

the angle of the plane of this pseudostome collar is usually zero degrees, but can some-
times be as high as 33°. The translucent and fragile organic shell is covered with small
irregularly-shaped thin and flat quartz particles. Larger particles are located on the
dorsal and distal part of the shell and smaller particles on the ventral side. The rim of
the collar is covered with relatively large flat particles. The organic matrix is colorless
to dark brown. Length including the collar 45-54 um; main body width 26-30 um,
height 17-30 um; collar 20-29 um across (n=6).

Etymology. The specific name refers to the area where the species was found,
the Dinarides or Dinaric Alps, Latin: dinarica, a mountain range in, among others,
Croatia and Bosnia and Herzegovina.

Type material. ‘Three slides, one with the holotype and two with paratypes, were
mounted in HYDRO-Matrix on glass slides and deposited in the collection of the

62 Najla Bakovié et al. / Subterranean Biology 45: 53-74 (2023)

Croatian Biospeleological Society under accession numbers TAM4 (holotype), TAM5
and TAM6G (paratypes).

Type locality. Croatia, Lika region, Lipovo polje, Drazice ponor, 44°46'20.2"N,
15°11'10.6"E, 10 November 2018, H. Bilandzija leg.

Differential diagnosis. There are several testate amoebae similar in shape and
size to P dinarica: Centropyxis platystoma, Psammonobiotus communis, P. septentrialis
and P minutus, some Centropyxiella and Corythionella species, and Conicocassis
pontigulasiformis. Centropyxis platystoma was described by Penard in 1890, but in
1902 he considered this species identical to Leidy’s C. constricta (Penard, 1890, 1902).
Since he originally described it as Difflugia platystoma, the shell must have looked to
him as that of a Difflugia, with a dense covering of quartz particles. Penard described
the shell as “pierreuse”, stony. This is different from P dinarica, where the shell is
covered with tiny flat particles. In the original description, Penard showed a drawing
of the visor with a strongly inwardly curved edge, in contrast to the edge of the collar
of P dinarica which is not curved. P dinarica can be distinguished from P septentrialis
and P minutus by its larger size, 45-54 um long versus 10-12 um and 23-30 um,
respectively (Golemansky 1970; Chardez 1977a). The size is about the same as
P communis, 45-54 um (Golemansky 1967) versus 33-52 um, but P dinarica can
be distinguished from the latter by the kidney-shaped aperture. P dinarica also bears
some resemblance to Conicocassis pontigulasiformis, but this species is much larger,
82-90 um, and the test wall has a much more pronounced granular organic cement
and a circular aperture (Nasser and Patterson 2015). P dinarica can be distinguished
from Centropyxiella arenaria by its kidney-shaped aperture, and from C. elegans and
C. lucida by its smaller size, length 45-54 um versus 70-80 um and 70-81 um,
respectively (Golemansky and Todorov 2007). It can be distinguished from similarly
shaped Corythionella species (Golemansky 1970b) by the presence of small elliptical
or oval idiosomes in the latter genus.

Biogeography and habitats. Psammonobiotus dinarica was found in the Dinaric
karst of Croatia and in Bosnia and Herzegovina, in the caves Drazice ponor, Markov
ponor (both Lipovo polje, CRO) (Fig. 1, Table 1), Jopiceva cave-Bent system (Krnjak,
CRO) and Matesi¢eva-Popovacka cave system (Slunj, CRO) (Bakovié N., unpublished
data). One empty shell was found in a small karst spring near the Jopi¢eva cave-Bent
system (Krnjak, CRO) (Bakovi¢ N., unpublished data). This species was also report-
ed in the Velika Bukovacka and the Listvaca cave (both in Bosnia and Herzegovina)
(Bakovié et al. 2019). The altitude of these localities ranges from 210 to 950 m.a.s.l.
The species inhabits surface sediments of permanent cave streams (dominant), sedi-
ments of small cave standing waters (sinter pools and clay pools) and transitional habi-
tats (hygropetric). Only one observation of P dinarica on the shell of a living Congeria
jalzici was noted.

The following ranges of physio-chemical parameters were present in the habi-
tat of this species: water temperature 5.4-10.7 °C, pH 7.62-8.11, conductivity
161-338 pS/cm. It was only occasionally present in all investigated habitats, but al-
ways at low densities (up to 3.3 ind. in 1 ml of aquatic sediment).

Testate amoebae associated with the endemic cave bivalve Congeria jalzici 63

Table 2. Taxa diversity.

Taxa Location
DAN DRA MAR BUK CAK HOR PRA SAM

1 Centropyxis aculeata Ehrenberg, 1838

2. Centropyxis aerophila Deflandre, 1929 + + +

3 Centropyxis constricta (Ehrenberg, 1841) Penard, 1890

4 Centropyxis bipilata Bakovié, Siemensma et. al, 2019 + + +

5 Centropyxis elongata (Penard) Thomas, 1959 +

6 — Centropyxis laevigata Penard, 1890 + +

7 Centropyxis plagiostoma Bonnet et Thomas, 1955 +

8 Cryptodifflugia oviformis Penard, 1902 + +

9 Cyclopyxis eurystoma Deflandre, 1929 + + +

10 Cyclopyxis kahli Deflandre, 1929 +

11 Cyclopyxis sp 1 +

12 Cyclopyxis sp 2 +

13. Cyphoderia ampulla (Ehrenberg, 1840) Leidy, 1878

14. Cyphoderia laevis Penard, 1902

15 Cyphoderia sp. +

16 Difflugia lithophila Penard, 1902 + +

17 Difflugia lucida Penard 1890 +

18 Difflugia cf. pristis Penard, 1902 +

19 Difflugia oblonga Ehrenberg, 1838

20 Difflugia penardi Hopkinson, 1909 +

21 Difflugia pulex Penard, 1890 +

22 ~Difflugia sp 1 +

23 Difflugia sp 2 +

24 Difflugia sp 3

25 Euglypha sp. + +

26 Euglypha laevis Perty, 1849 +

27 ~—Euglypha rotunda Wailes & Penard, 1911 + +

28 Euglypha tuberculata Dujardin, 1841 +

29 Heleopera petricola Leidy, 1879 + +

30 Heleopera sp. +

31 Heleopera sylvatica Penard, 1890

32 Microchlamys patella (Claparéde et Lachmann, 1859) + + + +
Cockerell, 1911

33 Paraquadrula irregularis (Archer, 1877) + Hf
Deflandre, 1932

34 Parmulina sp. +

35 Phryganella paradoxa Penard 1902 +

36 Plagiopyxis declivis Bonnet, 1955

37 Psammonobiotus dinarica sp. nov. +

38 — cf Psammonobiotus linearis Golemansky, 1971 +

39 Pseudodifflugia gracilis Schlumberger, 1845 + +

40 ‘Testacea sp 1 +

41 Testacea sp 2 + +

42 ‘Testacea sp 3 +

43 Testacea sp 4 +

44 — Tracheleuglypha dentata (Vejdovsky, 1882) 1 + 1
Deflandre, 1928

45 Trinema enchelys Ehrenberg, 1838

46 Trinema lineare Penard, 1890 + + + + + +
Total 1 19 Dip 12 10 9 3

Locations: DAN — Dankov ponor, DRA — Drazice ponor, MAR — Markov ponor, BUK — Buklina, PRA — Prazina

pecina, CAK — Peéina u Cakovcu, HOR — Horvatova pecina, SAM - Samograd.

64 Najla Bakovi¢ et al. / Subterranean Biology 45: 53-74 (2023)

Plate 2. A Parmulina sp. B Euglypha laevis C Trinema lineare D Tracheleuglypha dentata E Phryganella
paradoxa F Psammonobiotus dinarica sp. nov. G Cryptodifflugia oviformis H Testacea sp 1 I Testacea sp. 2
J Testacea sp. 3 (stacked image) K Centropyxis laevigata. Scale bars: 20 um (A, I-K); 10 pm (B-H).

Remarks. The genus Psammonobiotus contains nine beach sand-dwelling species,
six recorded only from marine and brackish waters (Golemansky and Todorov 2004),
one exclusively from freshwater (P dziwnowi) (Nicholls 2005) and two also from marine
and freshwater bodies (P communis and P linearis) (Golemansky and Todorov 2004).
P dinarica is the second Psammonobiotus species to be reported exclusively from a fresh-
water biotope. All species known to date have been collected from the psammon from
beaches of marine water bodies and some large freshwater lakes (Golemansky and To-
dorov 2005). The presence of P dinarica in a (freshwater) cave system can therefore be
called surprising. However, it is not the first Psammonobiotus species to have been found
in another ecosystem. The website arcella.nl reports the presence of Psammonobiotus

Testate amoebae associated with the endemic cave bivalve Congeria jalzici 65

Plate 3. Psammonobiotus dinarica A shell in ventral view (type specimen) B shell in lateral view (type

specimen) C shell in ventral view D shell in lateral view E kidney-shaped aperture. Scale bars: 20 pm.
A-D stacked photomicrographs.

species in a relatively small lake, in organic sediment of a small shallow freshwater ditch,
in organic sediment of an isolated pond and in the soil of a peat bog, all in the Nether-
lands (Siemensma 2021). It shows that our knowledge about the presence and distribu-
tion of Psammonobiotus species in freshwater and soil biotopes is still very limited.

Regarding the presence of light, all species of the genus Psammonobiotus primarily
inhabit aphotic biotopes — cave sediments (P dinarica) and interstitial sand habitats (all
other species) (Golemansky and Todorov 2005).

Although living specimens of P dinarica have been observed, pseudopodia could
never be observed as these specimens were always firmly attached to sediment parti-
cles. The brown color, if present, disappears rapidly when the shell is embedded in
HYDRO- Matrix.

66 Najla Bakovié et al. / Subterranean Biology 45: 53-74 (2023)

Testate amoebae assemblages

Comparison of taxa diversity (Fig. 2) showed that most diverse were the sample of bats
guano (HOR_bg) and one sample from a sinter pool (CAK_sp) where guano was not
present. Diversity and abundance of testate amoebae in samples from caves inhabited
by C. jalzici did not show any specific deviation — they vary from low to medium di-
versity and abundance of taxa.

The highest taxa abundance (Fig. 2) was detected in the sample of bats guano
HOR_bg (74 ind. in 1 ml) and two other samples rich in bats guano: BUK_th (55
in. in 1 ml) and SAM _sp (41 ind. in 1 ml). Despite the high taxa diversity, samples
from Markov ponor showed relatively a low abundance of taxa (<25 ind. in 1 ml). The
lowest abundance was detected in samples of CAK_th2 (6 ind. in 1 ml), DAN _th,
DRA_th, CAK_sp, HOR_th (all 12 ind. in Iml) and PRA_th (13 ind. in 1 ml).

Regarding the abundance of individual testate amoebae in caves inhabited by
C. jalzici, the species that can be highlighted is Microchlamys patella. \t was present in
all the samples from these caves and it was relatively abundant - reaching 5—10 ind.
in 1 ml (average 7.08 ind. in 1 ml). In comparison, the abundance of six other testate
amoebae present in these caves was 0-3.3 ind. in 1 ml (average 0.41-1.25 ind. in
1 ml). Also, they were not present in all the samples.

Shannon diversity and Pielou’s evenness (Fig. 3) did not show specific difference
between caves inhabited with C. jalzici and other caves. The differences rather varied
depending on the individual samples. Highest Shannon index values were in samples
MAR thl1 (3.51), CAK_sp (3.08) and HOR_bg (3.07). The Pielou’s evenness was
higher in samples CAK_sp (0.97), CAK_th2 and DAN _th (both 0.96). The Shannon
diversity and Pielou’s evenness for the samples DAN_th and SAM_th were zero due to
the only one species present in the samples.

The differences between caves inhabited with C. jalzici and other caves were well
visible in Bray-Curtis similarity dendrogram based on diversity and abundance of the
testate amoebae (Fig. 4). Three main branches are distinguished: samples from caves
inhabited with C. jalzici (MAR_th1, MAR_th2, DAN_th, DRA_th), samples with
significant presence of bats guano (BUK_th, HOR_bg, SAM_sp) and other samples
from caves uninhabited by C. jalzici (all other). Among third branch it could be em-
phasized higher similarity of sample of terrestrial cave habitat (CAK_terr) with tran-
sitional habitats (CAK_thl, HOR_th, SAM_th) in contrast to branches containing

sinter pools (small aquatic habitats).

Discussion

This research contributes with the first data on testate amoebae inhabiting three
caves with the endemic and endangered cave bivalve Congeria jalzici, as well as with
data from five other caves in the Lika region. Species found in caves in this study
are mostly eurybiotic species also present in surface habitats, which is in accord with
literature data (Mazei et al. 2012). Among the recorded species is one known only

Testate amoebae associated with the endemic cave bivalve Congeria jalzici 67

PR
js)

Number of taxa
OrRFrNW Hh UW DN COO WO

120
100

Number of ind. in 1 ml

Samples

Figure 2. Diversity and abundance of testate amoebae (marker shape: triangle — transitional habitats, asterisk

— terrestrial habitats, circle — bats guano deposits, square — sinter pools; marker color: represent different caves).

from caves (Centropyxis bipilata) (Bakovié et al. 2019, 2022a) and one new to science
(Psammonobiotus dinarica sp. nov.). Species and forms known exclusively from caves
(Mazei et al. 2012; Bakovi¢ et al. 2019; Soler-Zamora et al. 2021), imply that caves
may harbor even more species new to science that have been confused with eurybiotic
species or have been overlooked (especially in understudied regions).

Despite the fact that an empty shell of P dinarica sp. nov. has been found once in
a small karst spring near Jopi¢eva cave-Bent system (unpublished data, N. Bakovic), it
does not prove beyond doubt that this species also occurs in surface waters, as it could
easily be washed away from the subterranean habitats. The full extent of its habitats
requires further study. As one individual of P dinarica was found on the shell of a live
bivalve C. jalzici, this raised the question of whether they were somehow connected.
There are many records of epibiotic ciliates associated with cave animals (Matjasi¢
1962; Dovgal and Vargovitsh 2010) together with some protists that are animal par-
asites (Gittleson and Hoover 1969), but there is currently no data to support that
P. dinarica is in some way related to C. jalzici in terms of interspecies relations.

The comparison of the testate amoebae diversity in the researched caves was lim-
ited due to the small number of samples examined and different time points in which
they were collected. Still results from 27 testate amoebae from Markov ponor (from
only nine samples) imply that their diversity in individual caves may be even higher
than previously reported from Vjetrenica cave in Bosnia and Herzegovina (25 spe-

68 Najla Bakovié et al. / Subterranean Biology 45: 53-74 (2023)

Shannon (H'(log2))
5
>

=H'/Log(S))
i=) io) jo) ee
BD &® BR WN

©
N

Pielou's eveness (J'

Fw wm FF F Ri FY FS wm KR ww FTF VF RR
RY; ~ v PZ oh Oe WY x < SY 7 ef Qv 7 /
ys Bar GP VP OV OS E77 ke AP OS 5 SS ss

Samples

Figure 3. Diversity indices based on testate amoebae assemblages (marker shape: triangle — transitional
habitats, asterisk — terrestrial habitats, circle — bats guano deposits, square — sinter pools; marker color:
represent different caves).

cies) (Ozimec et al. 2021) and Covo della Guera in Italy (21 species) (Mazei et al.
2012). Nevertheless, data from Baradla Cave (Hungary), where 45 species were found
by several researchers (Bereczky 1970), imply that the diversity of testate amoebae in
caves could be much higher. The high diversity of Markov ponor may be partly due
to flooding by the Lika river. These events could import some species from the surface
streams into cave. [he comparative study of testate amoebae inside the caves and the
riverbeds of sinking streams is completely missing in the literature data. The results on
taxa diversity, abundance (Fig. 2) and diversity indices (Fig. 3) from this research were
not inconclusive regarding the separation of caves inhabited by Congeria jalzici from
other caves. The differences between samples can be regarded as differences between
habitats and the presence of bats guano that have already been noted by other authors
(e.g. Golemansky and Bonnet 1994). When guano is present in caves, it has multiple
effects. It increases the suplly of nutrients, which boosts the diversity and abundance
of microorganisms, lowers the pH of habitats (Mulec et al. 2015) and provides a more
heterogeneous habitat for microorganisms (Bakovic et al. 2022a).

The main result of this research is the distinction between samples from caves
inhabited by cave bivalve C. jalzici and other investigated caves based on Bray-Curtis
similarity (Fig. 4). The caves inhabited by C. jalzici are seasonally completely or par-
tially flooded by the exogenous Lika river (for several weeks or even months). ‘These

Testate amoebae associated with the endemic cave bivalve Congeria jalzici 69

i
Transform: Log(X+1}
Resemblance: 317 Bray Curtis similarity
20+-
=, 40--
ic
£
? 60+
80+
1004+
FY r A A A * a. A FY a A @ a a ha
<= a ON fan] cos a - <= i oa oa mn oO ~N oO
“I a, =, =, a 2 = io a * aA a ” =, *,
=
f 22 ¢£ 82 24% 2 2 & &. 2 =] .z
> > x= 1) a) “” o a ep) ne) OO
Samples
Caves with C. jalzici Caves without C. jalzici

Figure 4. Bray-Curtis similarity dendrogram (marker shape: triangle — transitional habitats, asterisk — ter-
restrial habitats, circle — bats guano deposits, square — sinter pools; marker color: represent different caves).

flood events mark nutrient-rich periods in these caves as the Lika river imports organic
matter into cave habitats that are usually poor in organic matter (Simon et al. 2007).
Even after the floodwaters are drained, large amounts of organic material remain in the
cave (e.g. water left in cave pools, wood debris). The second way of introduction of sur-
face waters into the wider area of these caves is by water runoff (water losses) through
the Lika and Bakovac riverbeds and existing accumulation (artificial lake) Kruscica due
to the karstification of this area (Pavicié 1997), a phenomenon that is very common
in karst areas (Bonacci 1987; Bonacci and Rubinié 2009). Thus, the impact of surface
waters of the Lika and Bakovac rivers together with the artificial lake Krus¢ica can also
be present outside of the period of flooding.

During the dry period, the hygropetric in caves inhabited by C. jalzici visually
resembles hygropetric in caves not subjected to flooding, as they are also character-
ized by slowly seeping and dripping water. But one key difference is that they are
subjected to turbulent water movement during flood events that continuously wash
these surfaces, and then, over the time of the water depletion, the suspended ma-
terial is slowly depositing on the cave walls. Therefore, the results of this research
confirmed that the hydrological conditions create a distinct habitat for the testate
amoebae in caves that are subject to flooding. The impact of freshwaters on these
habitats is also confirmed by the relatively high abundance of Microchlamys patella.
It is an eurybiotic species, but is more dominant in the freshwater habitats (e.g. Yang
et al. 2005; Vincke et al. 2006; Davidova and Vasilev 2012) in contrast to terrestrial

and transitional habitats.

70 Najla Bakovié et al. / Subterranean Biology 45: 53-74 (2023)

The influence of bat guano was also detected in results of Bray-Curtis similarity
(Fig. 4), as the samples richest in bat guano (BUK_th, HOR_bg, SAM_ sp) are assort-
ed as separate branches, implying a specific response of testate amoebae on increased
energy input and increased habitat heterogeneity (Mulec et al. 2016; Bakovié et al.
2022a). Specific influence of bat guano was also noted by Golemansky and Bonnet
(1994), who mentioned a dense population of testate amoebae in bat guano deposits.

Conclusion

This study presents data on testate amoebae from eight caves of the Lika region in
Croatia including the description of a new species for science, Psammonobiotus dinarica
sp. nov. As heterotrophic protists in caves are scarcely researched, finding new species
implies that caves could harbor more, still unknown, protists. The analyses from this
study showed that testate amoebae assemblages differ in caves inhabited by Congeria
jalzici in contrast to other caves studied. These differences can be attributed to the sea-
sonal flooding that provides specific habitats for protists, as well as providing optimal
conditions for the survival of endangered endemic Congeria species. ‘This diversifica-
tion needs to be further studied to better understand the conditions that shape specific
protists assemblages. Except for the knowledge of cave testate amoebae, these cogni-
tions could further enhance our understanding of the cave ecosystem and the condi-
tions that sustain populations of C. jalzici.

Acknowledgements

We thank the following individuals that accompanied us in the field work: Damir
Basara, Predrag Rade, Hrvoje Cvitanovi¢, Gordan Poli¢é and members of the Croa-
tian Biospeleological Society and the Breganja Society. Special thanks to Vedran Su-
dar, Helena Bilandzija, Branko Jalzi¢é and Damir Basara who provided us with several
samples; Neven Mato¢éec and Ivana KuSan for the provision of additional microscopy
equipment for detail study of protists; Sandra Hudina for useful advices on statistics.
Special thanks also to Korana Bakovié for her technical support during the field trips.
This research was supported by the projects Biospeleological research in area of Lipovo
polje (HEP, 2016), Dedicated institutional funding for science (2020/21) - Ministry
of Science and Education, Republic of Croatia and non-project activities of the Soci-
ety ADIPA (2021) and the Croatian Biospeleological Society (2018). The study was
performed under permissions of the Croatian Ministry of Environmental Protection
and Energy (Class: UP/1-612-07 /16-48/77; Ref. No.: 517-07-1-1-1-16-4, Zagreb,
10.05.2016; Class: UP/I-612-07/17-33/03, Ref. No.: 17-07-2-1-2-17-3, 08.03.2017)
and the Ministry of Economy and Sustainable Development (Class: UP/I-612-07/21-
48/170, Ref. No.: 517-10-1-1-21-3, 16.07.2021.).

Some of the results from this paper have been presented at the 3" Symposium of
Freshwater Biology, 15 February 2019 in Zagreb, Croatia.

Testate amoebae associated with the endemic cave bivalve Congeria jalzici ral

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