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New distribution records of the Arctic bryozoan Uschakovia gorbunovi Kluge, 1946 in the Barents and Greenland Seas

Published online by Cambridge University Press:  26 July 2024

Olga Yu. Evseeva
Affiliation:
Murmansk Marine Biological Institute of the Russian Academy of Sciences (MMBI RAS), Murmansk, Russia
Alexander G. Dvoretsky*
Affiliation:
Murmansk Marine Biological Institute of the Russian Academy of Sciences (MMBI RAS), Murmansk, Russia
*
Corresponding author: Alexander G. Dvoretsky; Email: ag-dvoretsky@yandex.ru
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Abstract

The bryozoan Uschakovia gorbunovi was initially characterized as a constituent member of benthic communities of the Kara and East-Siberian Seas. The academic literature reports this species in the Barents Sea, but without accurate information on sampling locations. Also, there are no previous records of this species in the northern Greenland Sea near Svalbard. Our analysis of benthic collections obtained during the past two decades revealed the occurrence of four distribution records of Uschakovia gorbunovi within the Barents and Greenland Sea specifying its distribution: one in the northwestern part of the area and three others in the waters surrounding Svalbard. The new distribution records may be related to inadequate sampling efforts or the expansion of this Arctic species into the Barents Sea, which may be due to either natural processes such as ocean currents, or introduction by mobile benthic species such as snow crabs.

Type
Marine Record
Copyright
Copyright © The Author(s), 2024. Published by Cambridge University Press on behalf of Marine Biological Association of the United Kingdom

Introduction

Bryozoans comprise a distinct group of aquatic organisms that form colonies composed of interconnected individuals. The Bryozoa predominantly inhabit marine environments, with various species distributed across all oceans, ranging from the littoral zone to abyssal depths (Ryland, Reference Ryland2005). Bryozoans play a significant ecological role in marine ecosystems by contributing to temperate and tropical carbonate sediments (Taylor et al., Reference Taylor, Lombardi and Cocito2015), serving as a food source for other marine species (Lidgard, Reference Lidgard2008), and providing three-dimensional structures, attachment surfaces, and nursery grounds for various marine organisms, some of which have commercial importance (Wood and Probert, Reference Wood and Probert2013; Taylor et al., Reference Taylor, Lombardi and Cocito2015). Due to their limited mobility, bryozoans have developed diverse adaptations and life-history traits to thrive in different environmental conditions (Ryland, Reference Ryland2005). This characteristic makes them valuable indicators for assessing habitat conditions (Pagès-Escolà et al., Reference Pagès-Escolà, Hereu, Garrabou, Montero-Serra, Gori, Gómez-Gras, Figuerola and Linares2018).

Information regarding the distribution and spatial patterns of biodiversity, both for benthic organisms in general and specifically for bryozoans, is important for monitoring long-term changes in the marine environment and mitigating anthropogenic impacts on the ocean (Cusson et al., Reference Cusson, Archambault and Aitken2007; Cook et al., Reference Cook, Bock, Gordon and Weaver2018). The most comprehensive source for the diversity and distribution of Arctic bryozoans is a monograph by Kluge, originally published in Russian in 1962, and later translated into English and republished in 1975 (Kluge, Reference Kluge1962, Reference Kluge1975). Subsequent research has updated species lists and furnished new distribution records of Bryozoa in Arctic seas (Gontar and Denisenko, Reference Gontar, Denisenko and Herman1989; Denisenko, Reference Denisenko and Matishov2000, Reference Denisenko and Udodov2003, Reference Denisenko2009, Reference Denisenko2020, Reference Denisenko2022a, Reference Denisenko2022b; Gontar et al., Reference Gontar, Hop and Voronkov2001; Kukliński, Reference Kukliński2002; Kukliński and Hayward, Reference Kukliński and Hayward2004; Kuklinski and Taylor, Reference Kuklinski and Taylor2006).

Uschakovia gorbunovi is a bryozoan species belonging to the order Cheilostomatida, suborder Flustrina, superfamily Buguloidea, and family Bugulidae. It was initially described by Kluge in 1946 (Kluge, Reference Kluge and Buynitskiy1946), based on benthic surveys conducted along the continental slope of the Kara and East-Siberian Seas (on the Novosibirsk shallow water) at depths spanning from 64 to 698 m during the late 1930s. Uschakovia gorbunovi has been confirmed to exist in Arctic seas through subsequent surveys (Gontar and Denisenko, Reference Gontar, Denisenko and Herman1989; Denisenko, Reference Denisenko, Jackson and Jones2011, Reference Denisenko2022a) as well as in Iceland waters in the Greenland Sea (Micael et al., Reference Micael, Denisenko, Gíslason, Guðmundsson, Kukliński and Rodrigues2022; Denisenko, Reference Denisenko2022b). Hayward (Reference Hayward1994) recorded this species in the southeastern Faroes at depths of 610–1400 m in 1987 (Cook, Reference Cook2001). Denisenko (Reference Denisenko2022b) recently reported the occurrence of this species in the Barents Sea, but did not provide data on collection locations. Additionally, there is no information on the distribution of this species in the northern part of the Greenland Sea. New data on the distribution of this species can provide valuable insights into its ecology and expand our knowledge of the ways in which fauna formed and spread in former geological times.

The main objective of our study is to document new distribution records of Uschakovia gorbunovi in the Barents and Greenland Seas.

Materials and methods

In this study we used a dataset comprising more than 1500 benthic samples collected during 45 marine benthic surveys conducted in the Barents, Kara, and Laptev Seas over the past two decades (2003–2022). At each site three replicate samples were collected aboard research vessels at depths of 30–680 m using a Van Veen grab (0.1 m2 sampling area). The collected samples were washed through a 0.5 mm sieve and fixed with 4% neutral-buffered formalin. Alongside the benthic samples, environmental variables such as water temperature and salinity were also measured using standard devices such as CTD profilers at each sampling location.

The identification of bryozoans was undertaken using an MBS-10 stereomicroscope, following the guidelines outlined in the above mentioned monograph (Kluge, Reference Kluge1962). A total of four colonies of Uschakovia gorbunovi were found in the samples (Table 1). The first finding of this species dates back to 2005, with subsequent records spanning from 2017 to 2019 (Table 1). All colonies were attached to small pebbles.

Table 1. Characteristics of the sampling stations with records of Uschakovia gorbunovi in the study area

One bryozoan colony was photographed with a Cannon EOS DSLR camera for reference.

Results and discussion

Three colonies of Uschakovia gorbunovi were collected in Svalbard waters (two in the Barents Sea and one in the northern part of the Greenland Sea), while one was collected in the Makarov Strait, an area situated between Franz Josef Land and Novaya Zemlya in the northeastern Barents Sea (Figure 1).

Figure 1. Records of Uschakovia gorbunovi. Pink circle – initial finding by Kluge (Reference Kluge and Buynitskiy1946) in the East Siberian Sea, orange diamonds – initial findings by Kluge (Reference Kluge and Buynitskiy1946) in the Kara Sea, red triangles – present findings in the northern Barents Sea (the numbers correspond to those in Table 1).

According to the initial description by Kluge (Reference Kluge and Buynitskiy1946, Reference Kluge1962), a colony of Uschakovia gorbunovi is erect and arises from an ancestrula that is anchored by rhizoids, which then leads to the emergence of several founding zooids that exhibit the same ability to develop rhizoids. This erect, branched part of the colony develops from either one zooid or a compact sequence of linking zooids, which display an extraordinary degree of elongation. The branches of autozooids are grouped in alternating pairs and triads, before transitioning into a quadriserial configuration and subsequently undergoing bifurcation. This primary branch divides several times, creating a cluster of four to six branches. Autozooids possess a long, tubular, proximal gymnocyst that expands distally to surround an elongated opesia. Outward-facing zooids are equipped with a bipartite opesia, wherein the distal part is covered by a frontal membrane that surrounds operculum, and the proximal part is composed of the swollen bases of a pair of long, partially cuticular spines. In contrast, the inward-facing zooids show no spines, but they have an elongated opesia. Avicularia arise from the proximal gymnocyst of both zooid types; the subrostral chamber is significantly elongated and expands distally, forming a terminally hooked, acute rostrum. The presence of ovicells remains unidentified within this species.

Unlike Kluge (Reference Kluge and Buynitskiy1946), who recorded a fully developed colony (as suggested from his initial description and illustration), we were able to photograph a small colony consisting of either a young developing colony (according to its small size) or a fully developed colony with only one linking zooid (Figure 2).

Figure 2. Uschakovia gorbunovi Kluge, Reference Kluge and Buynitskiy1946 from the Barents Sea, 2017. (a) – general colony view, scale bar 5 mm, (b) – distal part of the colony, scale bar 0.5 mm, (c) – details of the colony, scale bar 0.5 mm.

Founding zooids, spines, and ancestrulae were likely missed during grab sampling – a process that may preclude successful collection of intact, delicate colonies of deep-water bryozoans with thinly calcified zooids. Unfortunately, the other three colonies found in the study area were severely damaged and also exhibited small sizes.

The length of our photographed colony was 5 mm. The lengths of the other colonies were 8 mm (No. 1), 4 mm (No. 3), and 4.5 mm (No. 4). Kluge (Reference Kluge1962) did not provide the total length of his colonies, while Cook (Reference Cook2001) described a colony with a length of 10 mm in the waters of the Faroe Islands and noted that the maximum length of the colonies from the Faroes was 15 mm. The zooids of the Barents Sea colony were yellowish in colour, with a length ranging from 0.75 to 0.87 mm and a width of 0.25 mm. These measurements coincide with the range observed by Kluge (Reference Kluge1962): 0.75–1.40 mm in length and 0.25 mm in width. Cook (Reference Cook2001) revealed autozooids lengths ranging from 0.76 to 0.83 mm.

Kluge reported that Uschakovia gorbunovi is a high-Arctic species that occurs at temperatures ranging from −0.90 to −1.40°C, while Micael et al. (Reference Micael, Denisenko, Gíslason, Guðmundsson, Kukliński and Rodrigues2022) recorded this species at −1.8 to −6.0°C. Our findings fall within this range (Table 1).

The frequency of Atlantic water inflows into high-latitude regions of the Barents Sea has been increasing (Frolova et al., Reference Frolova, Lyubina, Dikaeva, Akhmetchina and Frolov2007; Matishov et al., Reference Matishov, Moiseev, Lyubina, Zhichkin, Dzhenyuk, Karamushko and Frolova2012; Kortsch et al., Reference Kortsch, Primicerio, Fossheim, Dolgov and Aschan2015; Dvoretsky et al., Reference Dvoretsky, Vodopianova and Bulavina2023), resulting in stronger ocean currents and wind forcing (Matishov et al., Reference Matishov, Matishov and Moiseev2009, Reference Matishov, Moiseev, Lyubina, Zhichkin, Dzhenyuk, Karamushko and Frolova2012), may facilitate the range extensions of bryozoans. This phenomenon has been observed in both high and lower latitude areas of the Barents Sea over the past decade (Evseeva et al., Reference Evseeva, Ishkulova and Dvoretsky2022; Evseeva and Dvoretsky, Reference Evseeva and Dvoretsky2023, Reference Evseeva and Dvoretsky2024; Dvoretsky and Dvoretsky, Reference Dvoretsky and Dvoretsky2024). It can be hypothesized that Uschakovia gorbunovi was transported into the Barents Sea through the influx of cold Arctic waters from the Kara Sea between Franz Josef Land and Novaya Zemlya. This current then flows westward across the northern Barents Sea along the eastern slope of the Spitsbergen Bank, where it merges with the East Spitsbergen Current (Jakobsen and Ozhigin, Reference Jakobsen and Ozhigin2011). This circulation pattern provides a plausible explanation for the new distribution records of this bryozoan in the northern part of the Barents Sea. However, there emerges a question concerning the lack of early findings of Uschakovia gorbunovi in Svalbard waters, particularly since the species was discovered in the Faroe Islands based on a collection made in 1987. The bryozoan fauna in the shallow-water Svalbard area has been extensively studied (Gulliksen et al., Reference Gulliksen, Palerud, Brattegard and Sneil1999; Gontar et al., Reference Gontar, Hop and Voronkov2001; Kukliński, Reference Kukliński2002; Palerud et al., Reference Palerud, Gulliksen, Brattegard, Sneli, Vader, Prestrud, Strøm and Goldman2004). Uschakovia gorbunovi, which prefers deeper waters, was not found in collections prior to 2005, possibly due to insufficient sampling efforts in the open sea waters near the Svalbard Archipelago. Several bryozoan species have expanded their range through boat bottoms, ship hulls, and ballast water tanks (López Gappa et al., Reference López Gappa, Carranza, Gianuca and Scarabino2010; Ryland et al., Reference Ryland, Bishop, De Blauwe, El Nagar, Minchin, Wood and Yunnie2011; Loxton et al., Reference Loxton, Wood, Bishop, Porter, Spencer Jones and Nall2017; Anderson et al., Reference Anderson, Peterson and Andres2022). However, this pathway is only relevant for coastal species. In the case of the deep-water Uschakovia gorbunovi, a more likely scenario is their distribution via mobile benthic species, such as the invasive snow crab Chionocetes opilio. This species was first recorded in the Barents Sea in 1996 (Dvoretsky and Dvoretsky, Reference Dvoretsky and Dvoretsky2015), and adult snow crabs reached the Kara Sea in 2012 (Zimina, Reference Zimina2014). The migration of snow crabs in the opposite direction may have promoted the range extension of Uschakovia gorbunovi into the Barents Sea. Previous research has shown that snow crabs are suitable hosts for deep-sea bryozoans (Savoie et al., Reference Savoie, Miron and Biron2007) and that invasive crabs can contribute to the spread of their epibionts within the new area of occurrence (Dvoretsky and Dvoretsky, Reference Dvoretsky and Dvoretsky2022, Reference Dvoretsky and Dvoretsky2023).

Our study provides a basis for further monitoring of bryozoan fauna in Arctic seas under changing environmental conditions and a reference point for tracking the range expansion of bryozoans at high latitudes.

Data availability

The authors confirm that the data supporting the findings of this study are available within the article.

Acknowledgments

The authors thank the crew aboard R/V ‘Dalnie Zelentsy’ and MMBI colleagues for support in sampling. We are grateful to two anonymous reviewers for their valuable comments.

Author contributions

Olga Yu. Evseeva – Conceptualization, data curation, formal analysis, writing-review and editing. Alexander G. Dvoretsky – project administration, software, validation, writing-original draft.

Financial support

This study was funded by the Ministry of Science and Higher Education of the Russian Federation.

Competing interest

None.

Ethical standards

Not applicable.

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Figure 0

Table 1. Characteristics of the sampling stations with records of Uschakovia gorbunovi in the study area

Figure 1

Figure 1. Records of Uschakovia gorbunovi. Pink circle – initial finding by Kluge (1946) in the East Siberian Sea, orange diamonds – initial findings by Kluge (1946) in the Kara Sea, red triangles – present findings in the northern Barents Sea (the numbers correspond to those in Table 1).

Figure 2

Figure 2. Uschakovia gorbunovi Kluge, 1946 from the Barents Sea, 2017. (a) – general colony view, scale bar 5 mm, (b) – distal part of the colony, scale bar 0.5 mm, (c) – details of the colony, scale bar 0.5 mm.