Fact-checked by Grok 2 weeks ago

Omul

The omul (Coregonus migratorius), commonly known as the Baikal omul, is a species of belonging to the salmon family () that is endemic to in southeastern , . This slender, typically measures 30–60 cm in length and weighs 200 g to 1.5 kg, featuring light silver sides, a darker back, small spots on the , a terminal mouth, and 35–54 long gill rakers adapted for filter-feeding on . Native exclusively to —the world's oldest and deepest freshwater lake, located in —the omul has adapted to the lake's unique oligotrophic environment over approximately 20,000 years since migrating from the . It exists in three ecological forms: the pelagic Selenginskaya form, which spawns in the distant River and feeds primarily on ; the coastal North-Baikalian and Barguzinskaya forms, which spawn in rivers like the Upper ; and the near-bottom Posolskaya and Chivyrkuiskaya forms, which inhabit depths up to 350 m and consume amphipods and small fish. Spawning occurs in September–October in stony-pebble substrates at 3–13°C, with eggs hatching after 190–200 days in cold waters (0.2–2°C), and larvae emerging in April–May to feed on over 55 invertebrate species. The omul holds significant cultural and economic value as a in Siberian cuisine, often prepared smoked, as raw saguuday salad, frozen , or grilled on sticks, and is especially popular among travelers on the . It historically formed the backbone of local fishing communities' gastronomical identity and accounted for about two-thirds of Lake Baikal's commercial fishery. Conservation efforts for the omul have been ongoing due to population fluctuations from and environmental pressures, with imposing a moratorium on its commercial harvest starting in 2017, which remains in effect as of 2025 to aid recovery; ongoing measures include artificial breeding and annual releases of millions of larvae. Although assessed as Least Concern globally by the IUCN as of , it was classified as endangered in as early as 2004, facing ongoing threats from change-induced ecological shifts, , and .

Taxonomy and Classification

Scientific Name and Family

The omul is formally classified under the binomial name Coregonus migratorius Georgi, 1775, originally described as Salmo migratorius based on specimens from Lake Baikal. It belongs to the family Salmonidae, within the subfamily Coregoninae, a group encompassing the whitefishes characterized by their freshwater habitats and adaptations to cold environments. The genus Coregonus includes at least 68 species, primarily distributed in northern hemisphere lakes and rivers, with the omul representing a distinct endemic lineage adapted to the unique conditions of its sole habitat. Historically, the omul was treated as a subspecies of the Arctic cisco (Coregonus autumnalis migratorius Berg, 1932), reflecting its migratory behavior and superficial similarities to other Siberian coregonids, but genetic analyses have since confirmed its status as a full with no close relation to C. autumnalis. This separation was formalized in the mid-20th century, notably through the taxonomic revisions of L.S. Berg, emphasizing morphological and ecological distinctions from Arctic populations. Phylogenetically, C. migratorius forms a sister clade with the Baikal whitefish (Coregonus baicalensis), diverging from a common ancestor approximately 10,000–20,000 years ago, and occupies a basal position among Holarctic coregonids based on complete mitochondrial genome sequences. This lineage shares closer affinities with other Siberian whitefishes than with European or North American congeners, underscoring its evolutionary isolation in Lake Baikal.

Etymology and Common Names

The Russian common name for the fish is омуль (omul'), a term originating from northern dialects and widely used in to refer to this species. The name reflects its regional significance in and fisheries, with early records appearing in 18th-century descriptions of Siberian fauna. In English, it is commonly known as the Baikal omul, a designation that underscores its exclusive to in . This name emphasizes the species' unique within the world's deepest freshwater lake, distinguishing it from related found elsewhere. An outdated scientific is Coregonus autumnalis migratorius, previously recognized as a but now considered synonymous with Coregonus migratorius. The species received its initial scientific description in 1775 by German naturalist Johann Gottlieb Georgi, who named it Salmo migratorius based on specimens collected from Siberian waters flowing into . This early classification highlighted its migratory behavior, a trait later formalized in its modern by Lev Semenovich in 1932, who designated it as a pelagic form of adapted to the lake's conditions.

Ecological Forms

The omul (Coregonus migratorius) displays three primary ecological forms, each adapted to specific niches within Lake Baikal's diverse aquatic environment. These forms represent s shaped by habitat preferences and resource utilization, rather than distinct subspecies. The pelagic Selenginskaya form, the most abundant comprising approximately 50-60% of the population, is characterized by riverine spawning in the Selenga River, Lake Baikal's largest tributary. This form inhabits the epipelagic zone, featuring a streamlined, cigar-shaped body, large eyes, and notably long rakers numbering 47-52, which facilitate efficient filtration from the . In contrast, the coastal forms, including the North-Baikalian and Barguzinskaya , spawn in rivers like the Upper and inhabit nearshore areas; these exhibit slightly fewer rakers (typically 35-48) and feed on a mix of and other in shallower waters. The near-bottom forms, Posolskaya and Chivyrkuiskaya, occupy depths up to 350 m, spawning in small coastal tributaries like the Bolshoy Chivyrkuy River; they possess robust body shapes and counts of 35-44, adapted for consuming amphipods, gammarids, and small fish in benthic zones. These ecotypes were first systematically distinguished in the through morphological and analyses, with key studies emphasizing variations in , fin structures, and spawning behaviors over . Pioneering work by Misharin detailed these differences, highlighting how the forms exploit Baikal's stratified water layers—from shallow bays to abyssal depths—while maintaining partial that limits interbreeding. This minimal underscores their status as ecotypes within a single species, enabling coexistence amid niche partitioning. The diversification of these forms exemplifies in Lake Baikal's ancient, isolated ecosystem, where post-glacial colonization by ancestral led to rapid morphological evolution tailored to the lake's oligotrophic conditions and vertical habitat gradients. Over millennia, selection pressures from varying depths, temperatures, and prey availability have refined these adaptations, contributing to the omul's despite the lake's extreme isolation.

Physical Description

Morphology and Anatomy

The omul (Coregonus migratorius) exhibits a slender, elongated body typical of coregonid whitefishes, facilitating efficient swimming in the of . It features a terminal mouth positioned for capturing small prey and large eyes that can measure up to one-quarter of the head length, enhancing in low-light, deep-water conditions. The body is covered with small scales, numbering 60-70 along the , which contribute to hydrodynamic efficiency. A distinctive feature is the elongated first gill arch bearing 35-54 long, thin rakers, which serve as a sieving mechanism for filter-feeding on ; this structure varies slightly among morpho-ecological groups, with the pelagic form having the highest count (44-55). As a member of the family, the omul possesses an adipose located between the and caudal fins, providing stability during . It also maintains a well-developed , which regulates and enables habitation at depths exceeding 100 meters. Internally, the omul stores substantial energy reserves in the form of lipids to support reproductive demands and migrations. The trunk kidney displays specialized microanatomy, including elongated nephrons with unique podocyte and tubular ultrastructures, adapted for efficient osmoregulation in the oligotrophic, freshwater environment of Lake Baikal by facilitating ion reabsorption and dilute urine production.

Size, Weight, and Growth

The Baikal omul exhibits considerable variation in size across its morpho-ecological groups, with average adult lengths ranging from 25 to 40 cm depending on habitat preferences such as coastal, near-bottom, or pelagic zones. Maximum recorded lengths reach up to 56 cm. Adult weights typically average 200 to 500 g, though exceptional individuals can attain a maximum of 1.5 kg. Growth in the Baikal omul decelerates after around 6-8 years of age. This pattern reflects adaptation to the nutrient-rich pelagic environment, where the streamlined facilitates efficient and sustained in open waters. is subtle, with females generally attaining slightly larger sizes than males, as evidenced by average lengths of 37.8 cm versus 35.8 cm and weights of 669 g versus 553 g in reproductive cohorts. is determined through analysis of otoliths, revealing a lifespan extending up to 12-15 years.

Coloration and Adaptations

The omul displays a coloration characteristic of in pelagic fishes, featuring a dark greenish-gray surface that transitions to silvery-white sides and a pale ventral region, which helps reduce visibility against the light gradient in Lake Baikal's open waters. Faint spotting occurs along the back, and the iridescent scales reflect ambient light, contributing to effective from predators above and below. Slight color variations exist among the ecological forms, though these are subtle and primarily linked to habitat-specific rather than stark differences in hue. Key physiological adaptations enable the omul to thrive in Lake Baikal's cold, oligotrophic environment. The species exhibits tolerance to low temperatures, with recorded ranges down to in its preferred pelagic and deep-water habitats, supporting year-round activity in the lake's frigid depths. High olfactory plays a vital in detecting chemical cues during spawning migrations, as evidenced by adaptive rearrangements in the olfactory epithelium's supporting and receptor cells that enhance sensory function in the pre-spawning period. Visual adaptations are particularly pronounced in the deep-water morphotype, which possesses relatively large eyes suited to the dim conditions of depths exceeding 200 meters, where light penetration is minimal due to the lake's clarity and depth. This eye enlargement facilitates detection of prey and in low-light environments, distinguishing it from the smaller-eyed pelagic form.

Distribution and Habitat

Endemism to Lake Baikal

The Baikal omul (Coregonus migratorius) is strictly endemic to , the world's oldest and deepest freshwater lake, which formed approximately 25–30 million years ago during the epoch as part of the Baikal Rift Zone's tectonic activity. This ancient isolation has fostered a unique , where the omul represents one of the few coregonid species adapted exclusively to the lake's pelagic environment. Unlike many migratory coregonids that inhabit interconnected river-lake systems across the , the omul has no natural populations outside Baikal; occasional individuals that stray into outflowing rivers, such as the , fail to establish viable groups and typically perish due to unsuitable conditions beyond the lake's stabilized . The omul's traces back to the Pleistocene glaciations, beginning around 2 million years ago, when climatic oscillations and glacial advances isolated Baikal's from broader Eurasian freshwater networks. During this period, coregonid fishes underwent rapid adaptive radiations in ancient lakes like Baikal, leading to the divergence of the omul from ancestral forms that likely entered the basin via ancient river connections before full isolation. Post-glacial stabilization around 11,700 years ago further reinforced this separation, allowing the omul to evolve distinct ecological forms within Baikal without from external populations. Baikal's extreme depth, exceeding 1,600 meters, has played a key role in maintaining this habitat exclusivity by creating vertical gradients that support specialized pelagic niches unavailable elsewhere. Genetic analyses underscore the omul's isolation, revealing unique frequencies and minimal in noncoding genomic regions compared to other Baikal Coregonus . Studies using subtraction hybridization and sequencing show that the omul shares a recent common ancestry with Baikal's lacustrine (C. baicalensis), diverging within the lake approximately 10–20 thousand years ago, but exhibits fixed differences in immune-related gene loci, reflecting long-term in the closed Baikal system. Recent phylogenetic research supports an origin within rather than recent migration from the , with low interspecific hybridization potential due to ecological specialization within the C. lavaretus complex. Historical records of the omul date to the , when Russian explorers first documented the species during expeditions into . Johann Gottlieb Georgi, a German-Russian naturalist, provided the earliest scientific description in 1775, noting its abundance and migratory behavior in Baikal while mapping the region's and . These accounts, drawn from Cossack-led ventures reaching the lake's shores by the mid-1600s, highlighted the omul's ecological significance to Evenki and Buryat peoples long before formal .

Preferred Depths and Seasons

The Baikal omul maintains a primarily pelagic distribution within , inhabiting depths of 50-150 meters for the pelagic morphotype and 250-350 meters for the deep-water morphotype during the early spring transition period from late May to early June. Year-round, this distribution generally spans 50-200 meters, though the species ascends to the upper 50 meters in offshore and nearshore areas, including bays, during summer and autumn for feeding on planktonic prey. These depth preferences reflect the omul's adaptation to the lake's stratified , where its physostomatous facilitates adjustments during vertical movements. Seasonal shifts in depth usage are pronounced, with omul concentrating in the slope zones at 100-350 meters during winter to evade the ice-covered surface layers that form from to May. In , populations migrate from these deeper wintering grounds (100-300 meters on slopes) toward open-water feeding areas in the upper layers, a pattern observed during the post-ice thaw period. Shallower depths are also favored during autumn spawning runs, as adults move toward riverine tributaries for , contrasting with the deeper winter retreats. The omul associates closely with the , particularly in summer when this layer forms between 10 and 20 meters, allowing the species to exploit cooler, nutrient-rich mid-water zones while . Acoustic surveys conducted in the , including hydroacoustic assessments, have documented these patterns, revealing vertical migrations of over 100 meters as omul respond to gradients and prey availability, with pelagic forms shifting from 50-150 meters in to shallower positions seasonally. These studies highlight the species' dynamic use of the to optimize and avoid surface stressors like .

Environmental Conditions

Lake Baikal, an oligotrophic cold-water lake, maintains environmental conditions ideally suited to the omul (Coregonus migratorius), with surface water temperatures ranging from 0°C in winter to 14–16°C in summer, while deeper waters remain consistently at 3.3–3.6°C year-round. The omul, as a stenothermic , thrives in this narrow temperature range of 0–12°C, which supports its metabolic processes and distribution in the . The lake's high , exceeding 90% even at depths up to 1,642 m, ensures aerobic conditions essential for the omul's and overall survival in its preferred habitats. Low nutrient levels, particularly total concentrations below 0.01 mg/L (typically 0.001–0.012 mg/L), characterize the oligotrophic status of the lake, fostering a stable prey base upon which the omul depends without promoting excessive algal growth. Water in varies between 7.5 and 8.5, providing a to slightly alkaline compatible with the omul's physiological needs. Exceptional , with Secchi depths reaching up to 40 m in open waters, enhances visual efficiency for the sight-dependent omul. The omul exhibits sensitivity to environmental perturbations, thriving in these stable, pristine conditions but facing vulnerability from warming trends that could alter temperature profiles and prey availability.

Life History and Biology

Reproduction and Spawning

The Baikal omul (Coregonus migratorius) is an iteroparous that typically spawns annually, though some studies have debated aspects of its reproductive strategy in relation to environmental pressures; maturity is generally reached at ages 4–5 years for coastal morphs and up to 7–8 years for pelagic and near-bottom forms. Spawning migrations begin in late August to October, with actual spawning occurring from September to October in river tributaries such as the (110–250 km upstream from the delta), Barguzin, and streams in Posolskiy Sor Bay, or on nearshore gravel and sandy substrates at depths of 1.5–6.0 m in . During , males position themselves ahead of females, engaging in rhythmic parallel movements and body collisions to stimulate egg release; this occurs primarily at night in male-female pairs, lasting 2–4 seconds per act over 1–3 nights, with females participating in 20–100 such acts. Fertilization is external, with males releasing synchronously as females broadcast ; the are adhesive, demersal, and yellowish, measuring about 2.5 mm in diameter, attaching to or for . Females exhibit absolute individual ranging from 16,000 to 20,000 eggs on average (as of 2020 data), varying by morpho-ecological group and increasing with body size and ; for instance, pelagic forms average around 16,400 eggs, while near-bottom forms average around 19,900 eggs. Relative typically falls between 28–34 eggs per gram of body weight, decreasing slightly with advancing .

Growth Stages and Lifespan

The life cycle of the Baikal omul (Coregonus migratorius) encompasses distinct developmental phases from egg to adult, marked by environmental adaptations in Lake Baikal's cold waters. Eggs, laid during autumn spawning, undergo incubation for 190–200 days at temperatures of 0.2–2°C, typically from November to April–May. Hatching occurs in late April to early May, producing alevins measuring 10–12.5 mm in length and weighing 6–7 mg, which initially absorb their yolk sac while drifting toward the lake. The juvenile stage follows, lasting 1–3 years as alevins transition to exogenous feeding on planktonic organisms, consuming over 55 intensively for the first 30 days post-hatching. During this period, distinctive parr marks gradually fade, and the fish grow toward sub-adult sizes while inhabiting shallower lake areas. Maturation into the phase begins at lengths of 34–39 cm and ages of 5–15 years, varying by morpho-ecological group (pelagic, littoral, or deep-water). Adults, reaching up to 56 cm in length, exhibit iteroparity, spawning multiple times over their lifespan of up to 14+ years in the wild, with linked to declining reproductive output in older individuals. Mortality is notably high in the first year (estimated 50–90% for coregonid species due to predation and environmental stressors), decreasing to lower annual rates (10–30%) in later stages as survival improves with size and habitat shifts.

Diet and Trophic Role

The Baikal omul (Coregonus migratorius) is primarily a zooplanktivore, with mesozooplankton forming a substantial portion of its diet in the pelagic form, alongside amphipods and fish larvae. The dominant mesozooplankton prey is the endemic copepod Epischura baikalensis, which accounts for 80–90% of the total zooplankton biomass in Lake Baikal and thus constitutes the bulk of the omul's planktivorous intake. Other zooplankton components include copepods and cladocerans, while the amphipod Macrohectopus branickii and larvae of pelagic sculpins (Comephorus spp.) supplement the diet, particularly in coastal-pelagic and deepwater morphotypes. Omul exhibit an ontogenetic shift in feeding habits, with juveniles targeting smaller plankton such as rotifers and microcrustaceans like Daphnia spp., achieving daily growth increments up to 13% when fed mixed live plankton. As adults, they consume larger macrozooplankton and show occasional piscivory, though this remains rare and limited to small prey like sculpin juveniles. Feeding intensity peaks in summer, coinciding with maximum zooplankton availability in the upper pelagic layers. The omul's specialized gill rakers, numbering 35–54, enable efficient filter-feeding on these fine particles. In the , the omul occupies a central trophic position as a secondary consumer, channeling energy from primary producers—via herbivorous like E. baikalensis—to tertiary consumers. This role supports higher predators, including the endemic (Pusa sibirica), which consumes omul alongside dominant prey like golomyanka fish, thereby linking pelagic production to the lake's top carnivores. Variations in diet composition across morpho-ecological groups (pelagic, coastal-pelagic, and deepwater) reflect adaptations to depth-specific prey distributions, underscoring the omul's versatility in the hyperoligotrophic ecosystem.

Behavior and Ecology

Migration Patterns

The Baikal omul (Coregonus migratorius) exhibits distinct seasonal patterns, transitioning between feeding grounds in the pelagic zones of and spawning sites in its tributary rivers. In summer (July–August), the fish undertake feeding migrations, forming concentrations that extend from the southern to the central basins of the lake, primarily in the upper water layers where is abundant. These movements support growth and fat accumulation before the reproductive period. In autumn (September–October), omul initiate anadromous-like spawning runs from the lake's open pelagic areas to river mouths, targeting 22 inflowing rivers including the (47.2% of spawning grounds), Upper Angara (24.1%), and Barguzin (8.7%). The form travels the farthest, with maximum upstream distances of 580 km from the lake and averages of 192 km (ranging 85–350 km), while runs in the Upper Angara reach up to 373 km. Migration begins around August 31 and lasts about 1.5 months, with less mature individuals entering rivers earlier and proceeding farther upstream. These runs are guided by olfactory cues from river water and influenced by hydrological factors such as currents and flow rates, where decreased flows in the extend migration distances (inverse with flow, rS = -0.71 to -0.57). Group-specific variations occur, with the population showing the longest routes tied to maturity stages, whereas the Chivyrkuisky form in Chivyrkuisky Bay completes shorter local migrations to nearby inflowing rivers. Tracking studies from the 1990s–2020s, using methods like silk thread marking (e.g., 9,197 in , 1987–1994) and acoustic surveys, report average speeds of 5.5 km/day in the (ranging 2.7–10.3 km/day overall) and up to 11.5 km/day in northern rivers. Following spawning, omul return to the lake for overwintering, concentrating in slope zones of the southern basins at depths of 100–350 m, with scattered individuals in the lower epi-pelagic layer. During transitional migrations in spring and autumn, the occupy mid-water depths of 50–150 m.

Schooling and Social Behavior

The Baikal omul (Coregonus migratorius) forms dense aggregations that exhibit schooling behavior, enabling horizontal migrations and active pursuit of clustered food resources such as and amphipods, thereby enhancing foraging efficiency. These group formations, observed through hydroacoustic surveys, typically occur in the slope zones of at depths of 50–100 m during winter and early spring, where coordinate movements to exploit patchy prey distributions. In juveniles, schooling plays a in developing defensive reflexes, allowing young omul to respond collectively to threats and improve rates against predators. This supports predator avoidance by diluting individual risk within larger groups, a highlighted in studies of early . The omul's patterns briefly facilitate school formation by concentrating individuals in productive feeding zones during seasonal movements. Diel patterns influence schooling dynamics, with fish undergoing vertical redistributions , shifting from shallower depths of 80–115 m to deeper layers of 125–175 m at rates of about 50 m over 40 minutes, potentially tightening formations for protection during transitions to open water. At greater depths exceeding 200 m, omul display more passive behavior, contrasting with active schooling in upper layers. The species shows adaptations for acoustic sensitivity in its structures, including specialized sensory epithelia in the saccule and lagena, which may support non-reproductive interactions within , though direct evidence of sound production via the remains limited. Territoriality appears low, with interactions primarily driven by size-based hierarchies during feeding competitions rather than defended areas.

Predators and Symbiotic Interactions

The Baikal seal (Pusa sibirica) is the primary natural predator of the omul (Coregonus migratorius), though omul comprises only about 0.1% of the seal's diet by mass, with the majority consisting of golomyanka fish and sculpins. Despite this minor dietary contribution, the seal population consumes roughly 3% of the annual omul biomass, exerting top-down pressure on omul stocks. Other predators include the Siberian taimen (Hucho taimen), which targets spawning omul during autumn river migrations, particularly in coastal and tributary zones. Juveniles are particularly vulnerable to predation by smaller invertebrates and fish, including amphipods and benthic species, during early life stages in nearshore habitats. Adults mitigate predation risk through schooling behavior, which confuses predators and enhances survival in the . In terms of symbiotic interactions, the omul hosts several parasitic copepods, notably Salmincola lavaretus from the family Lernaeopodidae, which attaches to the gills and body surface, potentially affecting host respiration and energy allocation. These ectoparasites exhibit host specificity to coregonids like the omul, with infestation rates varying by age and morphotype; for instance, plerocercoids of cestodes such as Diphyllobothrium also commonly infect omul tissues. Commensal relationships are less documented, but the omul contributes to broader trophic cycles by linking pelagic plankton communities to higher predators, facilitating nutrient transfer in Lake Baikal's ecosystem. Declines in omul populations have historically prompted concerns over trophic cascades, with reduced availability potentially influencing seal foraging efficiency, though seals adapt by shifting to alternative prey like amphipods and non-commercial fish.

Conservation and Threats

Population Status and Trends

The Baikal omul (Coregonus migratorius), endemic to Lake Baikal, is classified as Least Concern on the IUCN Red List, with the assessment dated October 27, 2020, reflecting its overall global status despite localized pressures. However, its strict endemism to a single lake amplifies vulnerability to regional fluctuations. Recent hydroacoustic surveys in 2024 estimated the total population at approximately 37 million individuals, with a biomass of 8,600 metric tons across surveyed areas covering 2.8 million hectares, primarily concentrated in the Selenginsky shallow waters (51% of biomass, or 4,450 tons). These figures represent adult and juvenile stages combined, indicating a stabilized but modest abundance compared to historical levels. Historical population trends show significant fluctuations, with pre-1950s abundance supporting annual commercial catches peaking at around 10,000 metric tons during the , driven by mechanized and wartime demand, suggesting a much larger overall at that time. A sharp decline occurred post-1950s, coinciding with the construction of the Irkutsk Dam and intensified exploitation, leading to critically low catches by the late and emergency restrictions in the . The population further decreased from the mid-1990s to 2010, reaching historic lows between 2018 and 2020, after which a partial recovery has been observed since 2021, with biomass increases in areas like Barguzin Bay and the Small Sea, attributed to strong from the 2020 generation. Monitoring of population status relies primarily on hydroacoustic surveys conducted annually since 2021 using EK500 sonar systems across key polygons, including deep and coastal zones, to assess abundance and distribution. Complementary methods include catch-per-unit-effort data from limited indigenous fisheries and mathematical modeling such as TISVPA (Tuneable Instantaneous Surplus Yield Per Age) for forecasting stock dynamics and recruitment. These approaches have enabled projections of potential biomass growth to 20,000 tons by 2030 under stable conditions.

Major Threats

Overfishing represents a primary to the Baikal omul (Coregonus migratorius), with illegal and unregulated catches significantly depleting spawning stocks. During the , undocumented illegal harvests were estimated to reach up to 1,000 tons annually, exacerbating pressure on the population alongside legal quotas that often exceeded sustainable levels. This intensive exploitation disrupted reproductive cycles by targeting mature individuals during spawning migrations, leading to reduced and long-term declines in abundance. Pollution from industrial effluents has introduced persistent contaminants into , directly affecting omul health and habitat quality. The Baikalsk Pulp and , operational from 1966 until its permanent closure in 2013, discharged untreated wastewater containing such as , lead, , and mercury into the southern basin, elevating concentrations 1.5 to 2 times above natural levels near discharge sites. These toxins bioaccumulate in the omul's , particularly through and benthic organisms, causing physiological stress, genetic mutations, and decreased spawning success in affected populations. Climate change is altering Lake Baikal's thermal regime, with surface water temperatures rising approximately 1.2°C since the 1940s—equivalent to a 1–2°C increase from the onward—disrupting omul . This warming strengthens summer , shifting plankton communities toward warmer-adapted species like cladocerans at the expense of copepods, which form a key component of the omul's and influence its growth rates. Additionally, reduced cover duration (shortened by up to 15 days since the ) modifies hydrological cues for spawning migrations, potentially desynchronizing reproductive timing with optimal riverine conditions in tributaries like the . Introduced pose competitive risks to the omul by overlapping in trophic niches and resource use. The peled (Coregonus peled), intentionally introduced to in the mid-20th century for , has established self-sustaining populations and competes directly with omul for and benthic prey, particularly in pelagic zones. This competition, combined with potential hybridization risks, threatens the endemic omul's foraging efficiency and population stability in a already stressed by other factors.

Protection Measures and Research

The Baikal omul (Coregonus migratorius) benefits from several regulatory measures aimed at within , designated as a in 1996 to preserve its unique , including endemic fish species like the omul. Russian federal laws, such as the 2004 Law on and Conservation of Aquatic Biological Resources, establish total allowable catches and prohibit fishing during spawning migrations, with specific bans on targeting juveniles to protect reproductive . Following declines, a three-year commercial fishing moratorium was imposed from October 2017 to address , extended through 2022, with limited trialed in select areas starting in 2023; as of 2025, the industrial ban continues, while remains restricted under low total allowable catches (e.g., 150 tons in 2023). Quotas for allowable catches have historically targeted stable levels around 3,000 tons annually to maintain stock viability, though actual harvests in the early averaged about 1,000 tons before the ban. Hatchery programs play a key role in omul restoration, particularly through artificial spawning initiatives at the Listvennichnaya Bay facility near , where mature omul are collected during upstream migrations for egg incubation and fry rearing. This hatchery, modernized with federal funding since 2019, releases millions of omul larvae annually into and tributary rivers to bolster wild populations; for instance, over 338 million larvae were released in 2022 alone as part of broader efforts aiming for 1.5 billion fry per year across multiple species. These programs emphasize preservation by sourcing from various spawning rivers, contributing to survival rates that support gradual stock recovery post-moratorium. Ongoing research focuses on among omul ecotypes to inform strategies, with studies in the 2010s revealing adaptive differences between pelagic and near-shore forms through analysis of brain tissues, highlighting subtle genomic variations that underpin ecological specialization. Such work underscores the ' low overall but identifies distinct lineages tied to spawning sites, aiding targeted protection of vulnerable subpopulations. modeling efforts project future impacts on omul spawning s, particularly in the River, where warmer temperatures and altered could shift migration distances by up to 50-100 km by mid-century, potentially reducing suitable spawning habitat under various emission scenarios. International collaboration enhances these protections through the 1995 Russia- Agreement on the Protection and Management of Transboundary Waters, which targets the Selenga River—the primary omul spawning tributary originating in —for pollution control and sustainable resource use. This bilateral framework promotes joint monitoring and enforcement to mitigate upstream threats, with recent reaffirmations in 2024 emphasizing shared for migratory species like the omul.

Human Interactions

Historical and Commercial Fishery

The indigenous Buryat and Evenki peoples of the region have engaged in for omul using netting techniques since at least the pre-17th century, relying on the as a vital protein source during seasonal migrations. These early practices were localized and sustainable, centered on riverine spawning runs where nets were deployed from shore or small boats to capture schools without depleting stocks. Commercial exploitation of omul expanded significantly during the 19th and 20th centuries under tsarist and Soviet influences, transitioning from artisanal efforts to industrialized operations driven by growing demand and improvements like . This boom peaked in the , with annual harvests reaching approximately 10,000 tons amid wartime needs and mechanized fleets, though it contributed to early signs of overharvest impacting population levels. Primary methods included gillnets and trapnets set during spawning aggregations in tributaries, allowing efficient capture of the pelagic in shallow waters. Since the imposition of a commercial fishing moratorium in (extended beyond the initial three years), industrial harvesting of omul has been prohibited, with hydroacoustic surveys now primarily used for stock monitoring and management to aid recovery. Limited recreational and is permitted under strict regulations, including seasonal bans, to prevent further declines. of smoked omul to dates back to the 1800s, establishing it as a prized transported via emerging routes, with post-Soviet regulations introducing stricter limits and seasonal bans to sustain the .

Culinary and Cultural Uses

The omul is traditionally prepared fresh in ukha, a clear Russian fish soup simmered with potatoes, onions, carrots, and herbs to highlight its delicate flavor. It is also commonly smoked using alder wood for a subtle, aromatic taste, either hot-smoked for tenderness or cold-smoked for preservation, and cured through salting as an appetizer or stroganina, thinly sliced frozen raw fish seasoned with salt, pepper, and onions. Additional methods include roasting on wooden skewers over an open fire after salting and gutting, or serving raw in sagudai, a Siberian salad mixed with oil, onions, salt, and pepper. Nutritionally, omul offers 150-200 kcal per 100 g, with a protein content of approximately 18 g per 100 g and variable fat levels ranging from 1.3 to 10.3 g per 100 g depending on season and maturation stage. It is particularly rich in omega-3 fatty acids, providing 2-3 g per 100 g in fattier specimens, primarily as (EPA) and (DHA), alongside vitamins A and D essential for vision, bone health, and immune function. Culturally, omul serves as a central dish at the annual in Listvyanka near , a gastronomic event since the 2000s where Siberian restaurants compete in preparing omul-based recipes amid ice sculptures and folk performances celebrating Lake Baikal's heritage. In Buryat traditions, it symbolizes life's bounty from the sacred lake, integral to as a gift from Baikal's spirits and a staple in rituals honoring the ecosystem's balance. In local markets like those in Listvyanka, fresh and smoked omul is sold directly by vendors, typically priced at 500-1000 per in the , reflecting its status as an accessible regional .

Economic and Tourism Impact

The Baikal omul plays a significant role in the regional economy of the , particularly through its historical and ongoing contributions to the inland fisheries sector. Prior to the 2017 commercial fishing moratorium, the omul contributed up to 40% of industrial catches in the region and represented a key commercial species in Lake Baikal, comprising 35-48% of the region's total inland production. Yields had reduced to under 1,000 metric tons by 2015 due to stock declines. As of 2025, the commercial ban continues, with 2024 stock assessments indicating potential for recovery and late-2024 proposals for limited trial fishing; the focus has shifted to non-commercial activities, though specific current economic values from omul are limited by the restrictions. Tourism represents the primary contemporary economic driver linked to the omul, attracting visitors eager to its renowned flavor via tasting sessions and guided fishing excursions. draws over 500,000 tourists annually to areas like Maloye More, where omul-focused activities form a core part of itineraries, including boat fishing and culinary tours that highlight the species as an endemic . Overall visitation to the lake reached approximately 3 million people per year as of the early , though international numbers have declined post-2022 due to geopolitical factors, with sustaining growth; omul-related experiences continue to boost local and transport revenues. Efforts in sustainable branding have emerged since the to promote responsible omul harvesting and enhance , including proposals for ecosystem-based that preserve ichthyofauna diversity and enable for certified products amid the moratorium. These initiatives align with broader Baikal strategies, fostering consumer trust and higher returns for compliant producers. The omul supports jobs in the through processing, guiding, and ancillary services, particularly in tourism-dependent communities around the lake, where projects multiply employment opportunities in and related sectors. Cultural festivals briefly reference the omul to amplify its appeal, drawing additional crowds without overshadowing core economic channels.

References

  1. [1]
    Baikal Lake Omul - Arca del Gusto - Slow Food Foundation
    Baikal omul is a whitefish endemic to Lake Baikal, a slender fish with light silver sides and a darker back, and is considered a food delicacy.
  2. [2]
    Baikal omul
    The Baikal omul is a famous migrating whitefish with a terminal mouth, long gill rakers, small scales, large eyes, and small size. It has three groups.
  3. [3]
    Russia places moratorium on fishing threatened Baikal omul
    Nov 9, 2017 · According to the Russian government, the three-year ban on omul fishing is assumed to be enough for recovery of the species, but the ban will be ...
  4. [4]
    https://www.fishbase.se/Summary/SpeciesSummary.php?id=4788
  5. [5]
    Coregonus migratorius summary page
    ### Taxonomy Summary for Coregonus migratorius (Baikal Omul)
  6. [6]
    FAMILY Details for Salmonidae - Salmonids - FishBase
    Nov 29, 2012 · Salmo hamatus Cuvier, 1829. synonym, junior, original. Salmo ocla ... Coregonus migratorius (Georgi, 1775). accepted, senior, new. Salmo ...
  7. [7]
    Family SALMONIDAE Jarocki or Schinz 1822 (Salmonids)
    ... Cuvier 1829 presumably a Latinization of palée, its local name in ... Coregonus migratorius (Georgi 1775) Latin for migratory, referring to its ...
  8. [8]
    Complete mitochondrial genomes of Baikal endemic coregonids ...
    Baikal endemic coregonids, limnetic omul (Coregonus migratorius), and benthic lacustrine whitefish (Coregonus baicalensis) are the only representatives of ...
  9. [9]
    [PDF] Grouping of Baikal omul Coregonus autumnalis migratorius Georgi ...
    The history of studies on the origin and taxo- nomic status of the Baikal omul, Coregonus autumnalis migratorius, is typical of the difficul- ties that ...Missing: classification | Show results with:classification
  10. [10]
    значение слова в словаре Даля. Что такое Омуль? - Культура.РФ
    ОМУЛЬ м. арх. сиб. рыба, из рода лососей или сигов, Coregonus Omul, s. O. migrftoris. Омулевая икра. Омулевая погода, омулево погодье, осенний (авг.) мелкий.Missing: этимология | Show results with:этимология
  11. [11]
    Stock structure of Lake Baikal omul as determined by whole-body ...
    Apr 19, 2005 · In Lake Baikal, three morphotypes of omul Coregonus autumnalis migratorius are recognized; the littoral, pelagic, and deep-water forms.Missing: ecotypes | Show results with:ecotypes
  12. [12]
    Unexpected Discovery of an Ectoparasitic Invasion First Detected in ...
    Oct 21, 2022 · The omul, Coregonus migratorius (Georgi, 1775), is the main species sought by the commercial fishery in Lake Baikal (Eastern Siberia). The ...
  13. [13]
    [PDF] Some biological characteristics of the reproductive gild of Baikal ...
    Abstract. The aim of this work is to study some biological features of the near-bottom morpho-ecological group (MEG) of Baikal omul, Coregonus migratorius, ...
  14. [14]
    https://www.mdpi.com/2410-3888/7/5/298
  15. [15]
    [PDF] The geography of speciation and adaptive radi- ation in coregonines
    The lack of a thoroughly sampled phylogeographic context mean the Baikal omul and its three eco-mor- phological forms could have arisen from single lineage ...
  16. [16]
    Unique and ancestral features in trunk kidney microanatomy and ...
    Oct 30, 2025 · This study presents novel data on the microanatomy and ultrastructure of the omul Coregonus migratorius trunk kidney.
  17. [17]
    Lipid Accumulation and Fatty Acid Composition During Maturation of ...
    Total lipid content of all fish samples ranged from 7.8 to 345.1 (mg/g wet weight). Lipid class and fatty acid composition showed significant shifts with ...
  18. [18]
    Unique and ancestral features in trunk kidney microanatomy and ...
    This study presents novel data on the microanatomy and ultrastructure of the omul Coregonus migratorius trunk kidney. Adult individuals of C. migratorius ...
  19. [19]
    Comparative morphological characteristics of spawning populations ...
    The spawning population of the Baikal omul was represented by three MEGs, specimens of the. Selenga population were the largest in size, larger than the ...Missing: sources | Show results with:sources
  20. [20]
    Coregonus migratorius summary page
    ### Summary of Coregonus migratorius (Baikal omul) Size, Length, Weight, Growth, Lifespan, Dimorphism
  21. [21]
    [PDF] Morphological characteristics of the reproductive Gild of Baikal Omul ...
    The minimum number of gills rakers on the first- gill arch was observed in 1.5% of specimens and made 36 pcs, and a maximum of 43 rakers was ob- served in 3 ...
  22. [22]
    Fatty acid composition of salted and fermented products from Baikal ...
    Sep 18, 2019 · The omul (Coregonus autumnalis migratorius), also known as Baikal omul, is a whitefish species of the subfamily Coregonidae in the salmon family ...Missing: taxonomy | Show results with:taxonomy
  23. [23]
    Omul - Facts, Diet, Habitat & Pictures on Animalia.bio
    The omul, Coregonus migratorius, also known as Baikal omul (Russian: байкальский омуль), is a whitefish species of the salmon family endemic to Lake Baikal ...Missing: name | Show results with:name
  24. [24]
    (PDF) Aquatic prey use countershading camouflage to match the ...
    Jun 20, 2025 · Fish adjusted their countershading pattern in response to changes in the light environment, but the observed reflectance profiles did not match ...Missing: Baikal omul
  25. [25]
    Olfactory navigation during spawning migrations: a review ... - PubMed
    In this review, we synthesize research that explores the role of olfaction during the spawning migration of anadromous fish.Missing: Baikal omul adaptations
  26. [26]
    Stock structure of Lake Baikal omul as determined by whole‐body ...
    Aug 7, 2025 · In Lake Baikal, three morphotypes of omul Coregonus autumnalis migratorius are recognized; the littoral, pelagic, and deep-water forms.
  27. [27]
    Lake Baikal - UNESCO World Heritage Centre
    Situated in south-east Siberia, the 3.15-million-ha Lake Baikal is the oldest (25 million years) and deepest (1,700 m) lake in the world. It contains 20% of ...Missing: formation | Show results with:formation
  28. [28]
    [PDF] Microevolution of Bailkal omul Coregonus autumnalis migratorius ...
    Coregonids, which have evolved into a myriad of forms, subspecies and species during and after the Pleistocene glaciations, are rich subjects for the study of ...
  29. [29]
    (PDF) Genome similarity of Baikal omul and sig - ResearchGate
    Aug 6, 2025 · In this work, we studied genomic polymorphism of these two fish species. The method of subtraction hybridization (SH) did not reveal the ...
  30. [30]
    Mitochondrial DNA variability among Lake Baikal omul Coregonus ...
    This study was designed to assess the genetic variation of three different omul morphotypes sampled from different locations in Lake Baikal that were segregated ...
  31. [31]
    https://www.researchgate.net/publication/24308464_Genome_similarity_of_Baikal_omul_and_sig
  32. [32]
    https://pubs.usgs.gov/publication/70023934
  33. [33]
    Lake Baikal - FEOW
    Other noteworthy fishes​​ The major historical object of fisheries in Lake Baikal was Baikal omul' (Coregonus migratorius), although its yields have declined ...Missing: naming Cuvier
  34. [34]
    Climate Change and the World's “Sacred Sea”—Lake Baikal, Siberia
    May 1, 2009 · Reaching oceanic depths, Lake Baikal holds 20% of Earth's liquid freshwater (equivalent to all of the North American Great Lakes combined).
  35. [35]
    Current assessment of nitrogen and phosphorus content in the river ...
    Analysis of long-term data showed that the content of Ptot in the water of tributaries of the south-eastern coast of Lake Baikal is mainly low, at 1-12 µg/L.
  36. [36]
    Environmental monitoring of Lake Baikal
    The pH values remained within the range of 7.6–7.9 pH units, and the content of dissolved oxygen within the range of 10.8–11.7 mg/l. In 2021 the mineralization ...
  37. [37]
    Baikal water
    In regions with greatest depths in the southern and middle troughs. Secchi disk measurements have shown 40 m on the surface (standard - the Sargasso sea: 65 m.) ...<|separator|>
  38. [38]
    Modelling future hydroclimatic effects on the Coregonus migratorius ...
    Aug 1, 2019 · Modelling future hydroclimatic effects on the Coregonus migratorius spawning migration in the Selenga River and Lake Baikal.
  39. [39]
    Spawning Migrations of the Baikal Omul - IOPscience
    It reveals the features of spawning migration to latitudinal rivers. We show that the space and time structure of omul spawning is genetically determined.
  40. [40]
    Influence of abiotic factors on incubation of Baikal omul eggs in the ...
    Omul has been found to avoid spawning at depths less than 1.5 m and greater than 6.0 m. Water velocity and ice thickness did not strongly influence the choice ...
  41. [41]
    [PDF] Spawning behaviour of whitefishes (Coregonidae)
    Coregonus migratorius (Baikal basin), C. peled, C. tugun, ...
  42. [42]
    [PDF] ~ Northern Yukon Fisheries Studies, 1971 - 1974. Volume 2
    Mar 31, 1975 · ing of the omu1, Coregonus migratorius (Georgi), in tributaries of ... Berg divides this species into 32 types, races, or subspecies ...<|control11|><|separator|>
  43. [43]
    Are the Laurentian Great Lakes great enough for Hjort?
    Jan 15, 2014 · ... omul and Comephorus spp. During the period of stratification ... J. M. . ,. Auditory and olfactory abilities of pre-settlement larvae ...
  44. [44]
    The Rise and Fall of Plankton: Long-Term Changes in the Vertical ...
    Feb 25, 2014 · Here we analyzed 45 years of data from Lake Baikal, the world's oldest, deepest, and most voluminous lake, to assess long-term trends in the depth distribution ...
  45. [45]
    https://waves-vagues.dfo-mpo.gc.ca/Library/15010.pdf
  46. [46]
    Nutrition of the Baikal seal and its role in the trophic structure of the ...
    Aug 6, 2025 · Conclusion: the basis of the diet of the Baikal seal is made up of small non-commercial pelagic fish species, therefore, even with a large ...
  47. [47]
    Spawning Migrations of the Baikal Omul - ResearchGate
    Aug 6, 2025 · The research finds that the remoteness of the spawning grounds used by omul in the Selenga River correlates with the maturity of the female ...
  48. [48]
    https://eurekamag.com/research/025/795/025795064.php
  49. [49]
    (PDF) Distance of the Spawning Migration of Baikal Omul ...
    Jan 15, 2025 · The distance of migration has a high inverse correlation with the degree of maturity of the spawners, which is expressed by the maturity index ...Missing: growth | Show results with:growth
  50. [50]
    The bulletin of Irkutsk State University. Series «Biology. Ecology»
    The article is devoted to the analysis of data on Baikalian omul Сoregonus migratorius (Georgi, 1775) obtained using the hydroacoustic method of accounting.Missing: ecotype | Show results with:ecotype
  51. [51]
    Seasonal distribution of omul (Coregonus autumnalis migratorius ...
    Aug 7, 2025 · During the early spring transition period, pelagic omul reside in 50-150 m depth and deep-water omul in 250-350 m depth. At this time, the omul ...
  52. [52]
    The results of the first hydroacoustic studies of the winter distribution ...
    Aug 22, 2019 · We have obtained the first data on the distribution and behaviour of C. migratorius using the hydroacoustic recording of fish in the ...
  53. [53]
    Life skills training for hatchery fish: Social learning and survival
    Learned behavior can result from simple exposure of fish to conspecifics engaged in particular activities. Fish that observe a conspecific consume a novel food ...
  54. [54]
    (PDF) Ultrastructural correlates of acoustic sensitivity in Baikal ...
    Aug 7, 2025 · ... swim bladder walls or other gas-filled bladders to the inner ears. Swim bladders may be linked to the inner ears via a chain of ossicles (in ...
  55. [55]
    History of seal studies. Since ancient times the unique ... - Baikal.ru
    The seal usually lives under the water when the lake is covered with ice (December-early May). The whole population is located in the open Baikal.
  56. [56]
    lake Baikal seals
    The Baikal seal is peculiar amongst seals for its long life span, the maximum age of the female being 56, and of the male - 52 years.
  57. [57]
    Ecology of Siberian Taimen Hucho taimen in the Lake Baikal Basin
    Males reach sexual maturity at ages 7 to 8 and later for females at ages 8 to 9. Average egg production per female was about 22,000 eggs. Parasite burdens are ...
  58. [58]
    http://baikal.ru/en/baikal/excursion/
  59. [59]
    Lernaeopodidae): A parasite of coregonid fishes of Siberia
    May 15, 2016 · Data on the infestation of certain fish species by the parasitic copepod Salmincola lavaretus are presented for the first time.
  60. [60]
    Dynamics of parasite communities in an age series of Baikal omul ...
    May 24, 2014 · The peculiarity of the dynamics of parasite communities of Baikal omul is determined by specific features of the host physiology and ecology, ...Missing: adaptive radiation ecotypes
  61. [61]
    Stable isotope analyses of the pelagic food web in Lake Baikal - ASLO
    and is thought to be due to differential lipid content in or- ... Intraspecific structure of Baikal Omul, Cor- egonus autumnalis migratorius (georgi).
  62. [62]
    Chromosome-Length Assembly of the Baikal Seal (Pusa sibirica ...
    We connect this period to the time of migration to Lake Baikal, which occurred ~3–0.3 Mya, after which the population stabilized, indicating balanced habitat ...<|control11|><|separator|>
  63. [63]
    https://link.springer.com/article/10.1134/S1062359013050038
  64. [64]
    Catch estimates for omul (a) and nerpa (b) in Lake Baikal, showing...
    The unsustainability of this fishing method was recognized as early as the 1820s, but it continued in some form until the 1950s, even after the establishment of ...Missing: ecotypes | Show results with:ecotypes
  65. [65]
    Eco-legal and economic aspects of developing Malomorsky fishing ...
    A special place in the unique fauna of the lake holds Baikal omul, i.e. an endemic of Baikal and a valuable commercial fish species. There are tales and legends ...Missing: ecotypes | Show results with:ecotypes
  66. [66]
    Recent ecological change in ancient lakes - Hampton - 2018 - ASLO
    Jul 13, 2018 · Ancient lakes have a long history of exposure to a changing environment, with significant fluctuations in air temperatures and precipitation ...
  67. [67]
    Tourism No Gentler on Baikal Than Industry - The Moscow Times
    Aug 2, 2012 · A 2006 study found concentrations of heavy metals including zinc, lead and copper at one-and-a-half to two times the normal levels in the ...
  68. [68]
    [PDF] Polluting the sacred Lake Baikal A case study from Siberia, Russia
    The Baikalsk Pulp and Paper Mill´s history goes back to the 60s. It was closed in. October 2008 following decades of critique about pollution of the lake and.
  69. [69]
    Sixty years of environmental change in the world's largest freshwater ...
    Attaining depths over 1.6 km, Lake Baikal is the deepest and most voluminous of the world's great lakes. Increases in average water temperature (1.21 °C since ...Missing: oxygen pH omul Coregonus migratorius
  70. [70]
    [PDF] The current problems of Lake Baikal ecosystem
    The main source of pollution is the River. Selenga, where increased concentrations of mineral compounds, suspended matter, oil products, phenols and heavy ...
  71. [71]
    [PDF] lake baikal basin transboundary diagnostic analysis - Home (closed)
    Baikal omul (Coregonus autumnalis migratorius). The cottoid fish, or sculpins, consist of 33 species (Sideleva 2001). They are typically small (< 20 cm) ...<|control11|><|separator|>
  72. [72]
    Russia spends US$12M to help restore fish populations
    Sep 13, 2019 · Russia allocated US$12M to modernize hatcheries, releasing 450 million fry in Lake Baikal since 2019, with a goal of 1.5 billion fry per year.Missing: Listvennichy Bay 1-2
  73. [73]
    Russia: Fish-breeding plants of the Federal Agency for Fishery ...
    Dec 19, 2022 · Fish farmers have released over 338 million larvae of the Baikal omul and 866 thousand juveniles of the Siberian sturgeon into Lake Baikal, ...<|separator|>
  74. [74]
    Differences in Brain Transcriptomes of Closely Related Baikal ...
    The most important candidate genes related to the adaptation of Baikal whitefish and Baikal omul, identified in this work, belong to the genes of cell ...Missing: phylogenetic | Show results with:phylogenetic
  75. [75]
    [PDF] Mission Report to Lake Baikal World Heritage Property
    May 5, 2025 · addressing pollution issues associated with the Baikalsk Pulp and Paper Mill. ... natural content in some mineral components, including some heavy ...
  76. [76]
    Russia and Mongolia Agree to Cooperate on Preserving Lake ...
    Sep 4, 2024 · Russia and Mongolia Agree to Cooperate on Preserving Lake Baikal and the Selenga River ... protection and natural resource management. The ...
  77. [77]
    The Fate of Fishing in Tsarist Russia in - Berghahn Journals
    Jun 1, 2013 · This article explores the history of fishing on Lake Baikal in an effort to understand the fish-human nexus, to expand our understandings of ...
  78. [78]
    (PDF) Fishery management of omul (Coregonus Autumnalis ...
    Aug 6, 2025 · The ecosystem of Lake Baikal has been recognized for its uniqueness as well as the need to preserve its natural structure and functions.
  79. [79]
    Estimation of the abundance and biomass of the Baikalian omul by ...
    Estimation of the abundance and biomass of the Baikalian omul by means of trawl-acoustic survey. General Biology; Published: 06 January 2013. Volume 447, pages ...Missing: fishing | Show results with:fishing
  80. [80]
    Baikal fish soup cooking - YouTube
    Sep 4, 2010 · Fish soup on Lake Baikal prepared by a local guide-fisherman. Fish used for this soup (omul (endemic species) and ... Russian Trout Soup (Ukha) | ...
  81. [81]
    Fish With an Indelicate Smell Is Siberian Delicacy
    May 3, 2000 · And finally, there is omul "s dushkom" -- with odor -- the delicacy of Baikal's mountainous eastern shore and a traditional dish of the Buryat, ...Missing: etymology | Show results with:etymology
  82. [82]
    10 dishes that you can taste only in Siberia - Russia Beyond
    06-Mar-2018 · Baikal omul. Omul is cooked in many ways: It's salted, smoked, boiled, or fried. The Baikal fishermen's traditional recipe is omul on skewers.<|separator|>
  83. [83]
    Lipid Accumulation and Fatty Acid Composition During Maturation of ...
    In August and September of 1993, samples were collected from Lake Baikal, Russia to examine the lipid composition of major fauna including phytoplankton, ...Missing: recognized separate
  84. [84]
    How to Visit Siberia's Frozen Lake Baikal in Winter - GlobeRovers
    May 5, 2021 · Once a year, Siberians gather in the lake-shore town of Listvyanka to celebrate the Omul Festival which is a gastronomic feast during which ...Missing: significance | Show results with:significance
  85. [85]
    EP 202 B - Omul Fish: The Delicious Treasure of Lake Baikal
    Mar 4, 2025 · Discover the captivating tale of the Omul fish, a unique delicacy from Lake Baikal in Siberia. Join us for a 5-minute journey as we delve ...Missing: etymology | Show results with:etymology
  86. [86]
    Nomos, Buryats, Sacred Lake Baikal, Olkhon Island
    Oct 19, 2023 · With regard to the Evenki, Baikal has shaped a kind of memory among them about fishing as not merely a subsistence activity, but also an ...
  87. [87]
    Omul Baikal Buy for 4 roubles wholesale, cheap - B2BTRADE
    Omul Baikal ; Price per kg. 4.204.2USD$ ; Minimum order. 30 kg ; Total. 126.00$.Missing: 2024 | Show results with:2024
  88. [88]
    [PDF] Fishing industry in the Irkutsk Region: resource potential ...
    The share of the Irkutsk part of the Baikal water area accounts for 22% of the commercial fish stocks of the Irkutsk region, which is because of the decrease ...
  89. [89]
    The Baikal Basin as a Transboundary Ecological and Economic ...
    Discover the challenges and potential solutions for the Baikal basin, a transboundary ecological-economic system. Explore the conflicts between global ...
  90. [90]
    The Rise of Lake Baikal Tourism and Its Environmental Impact
    Jul 21, 2021 · Increased tourism to Lake Baikal has had positive outcomes for the region in certain respects. Visitors bring much-needed revenue to the ...Missing: omul fishery Irkutsk
  91. [91]
    [PDF] Report on the state of preservation of the UNESCO World Heritage ...
    The total population size of the Baikal seal in 2022 was 160.3 thousand animals, which ... ban on catching Baikal omul along spawning migration routes; an ...<|control11|><|separator|>
  92. [92]
    Meeting on development of Baikal natural area - President of Russia
    Aug 4, 2017 · Of course, this is a very promising branch of the regional economy – it is interesting and generates revenue and creates jobs. Russian and ...
  93. [93]
    Lake Baikal - Global Great Lakes
    The endemic omul (Coregonus autumnalis migratorius) is a planktivorous arctic whitefish that accounts for two thirds of the annual commercial catch (Garmaeva, ...