﻿A zoogeographical analysis of true bugs (Insecta, Heteroptera) from Uzbekistan

﻿Abstract The purpose of this study is to perform a zoogeographic analysis of terrestrial true bugs (Heteroptera) in the Lower Amudarya Territory, Uzbekistan. According to the findings of a literature review, there are 149 species of terrestrial hemipterans in the Territory. All hemipteran species, with the possible exception of five, have most likely been misidentified. Until now, reliable information on the zoogeography of true bug species in Uzbekistan’s north-western region has not been published. The composition of species, diversity, and the proportion of endemism vary greatly across the country’s zoogeographic regions. The Heteroptera fauna of the Khorezm and Karakalpakstan can be divided into four groups: most species belonging to the Palaearctic region, with 125 species constituting 83.89% of the fauna; the second group of Holarctic origin is characterized by no more than ten species, which constitutes 6.71%; the third consists of endemics, 13 species or 8.72%; and one species (0.67%) is cosmopolitan. Much more research is needed to investigate distributions in a more northern climate. The introduction of invasive Heteroptera to the north-western part of Uzbekistan will increase and deserves further consideration.


Introduction
Heteroptera or true bugs are a large group with more than 40,000 species in approximately 50 families distributed across the world (Weirauch and Schuh 2011;Henry 2017a). In Russia, 760 species in 285 genera, and 35 families, are recorded (Vinokurov et al. 2010), however, more than 1250 species are distributed in Central Asia (Esenbekova 2013), and 700 species of true bugs are distributed in Uzbekistan (Animal World of Uzbekistan 2023).
The study of the fauna of true bugs by Central Asia region has been occurring for more than 170 years (Saprykin 2013). Many individuals have studied regional true bugs from 1995-2013 using the large, published Catalogue of Palaearctic Heteroptera (Catalogue of Palaearctic true bugs 2013).

Materials and methods
The study was conducted in a lowland area in the northwestern part of Uzbekistan along the lower sections of the Amudarya River: between 60' and 61' longitude and 41' and 42' latitude, at an altitude of 113-138 m above sea level. The vegetative cycle of plants lasts 200-210 days. The climate is continental, with an average annual precipitation of 80-90 mm, and average temperature ranges from -5 °C in January to 40 °C in July. The climate has been changing, and the temperature has risen in summer, reaching 50 °C in July (Gandjaeva 2019;Ruzmetov et al. 2022). The usual alkali soils are meadow, meadow-marsh, and marsh-sandy. The area is located in the steppe zone, as well as in the southern portion of the Aral Sea and the western part of the Khorezm oasis. The historic Amudarya delta is made up of river sediments. Sand can be found on the sections connecting with Karakum in the west and southwest. Minerals include limestone, sand, clay, and other building materials (Khamraev 2003).
For the analysis, we used zoogeographical categories of the heteropteran species that had been recorded earlier. Approximately 180 specimens of Heteroptera indexed in the territory of the Lower Amudarya River and were identified to 149 species in 89 genera, and two infraorders. These species were deposited in the Zoological collections of the Zoology Institute (ZIN) of the Academy of Sciences of the Republic of Uzbekistan.
The zoogeographic analysis of identified species in the Lower Amudarya was based on zoogeographical nomenclature by Emelyanov (1974). In brief, geographic longitude was used to establish the zone along its meridional boundaries.
The descriptive area nomenclature utilized in this work uses the concepts of physical geography and applies two axis coordinates: the latitudinal axis runs from north to south and is critical because it is used to determine climatic conditions of the distributed species, especially temperature; the longitudinal axis runs from west to east. In some species, the range coincides with the boundaries of the landscape zone and is labeled as Arctic (polar deserts, tundra), boreal (taiga), subboreal (broad-leaved forests), subtropical and tropical (evergreen forests) (Lopatin and Meleshko 2016).
We used the basic data on the geographic distribution of these species from the Catalogue "Heteroptera of the Palaearctic" Volumes I-VI, published by the Netherlands Entomological Society, Amsterdam (NES) (1995-2013) (Catalogue of Palaearctic true bugs 2013) to describe the analysis of the zoogeographic areas of terrestrial Heteroptera (Aukema et al. 2013) the database is continually updated.
An analysis of the occurrence and abundance of species on cultivated and wild plants were carried out by observing 50-100 plant specimens every day along the diagonal of the fields. The number of adult bugs, larvae of all ages, and egg clutches was recorded (Gandjaeva et al. 2021).
The number of species and their occurrence was calculated using the formula devised by Dajoz (2000): where Pi refers to the species that was found; P is an absolute number. Species are divided into four groups based on their frequency of occurrence: Constantly occurring species: F ≥ 50% Often occurring species: 25% < F < 50% Additional occurring species: 5% ≤ F < 25% Rarely occurring species: F < 5% The dynamics of the abundance of species was calculated using the formula of Zaime and Gautier (1989): where Ni is the coefficient of special observable species; N is the absolute number of all observable species.
The analyses of the dynamics of the numbers of species are also divided into four groups: Abundant: Ar ≥ 10 Frequent: 5 ≤ Ar < 10 Some: 1 ≤ Ar < 5 Few: Ar < 1

Results and discussion
Checklists of Heteroptera for the Khorezm region and Karakalpakstan Republic were published more than 20 years ago. Khamraev (2003) and Kulumbetova (1998aKulumbetova ( , b, c, 1999 listed several species found to the north of Uzbekistan and, respectively, but some species have yet to be discovered while others are rare or migratory. We carried out a comparative analysis of the lists of regional faunas using the data from Khamraev (2003) in the Khorezm Region and Kulumbetova (1998aKulumbetova ( , b, c, 1999 in the Republic of Karakalpakstan, which allowed us to determine regional features of the fauna in the Lower Amudarya (Table 1). Based on taxonomic distribution, this method enables the collection of data about species complexes with various zoogeographical characteristics (Table 1; Fig. 2). To classify the areas of the Lower Amudarya, information from Gandjaeva et al. (2021) was used (Fig. 2).
Entomologists (Kulumbetova 1998a(Kulumbetova , b, c, 1999Khamraev 2003) discovered five new species: Tarajala brevicornis (Reuter, 1879), Emblethis dilaticollis (Jakovlev, 1874), Aethus nigronervosus (Melichar, 1906), Microporus virgata (Fabricius, 1974), and Sciocoris helferi (Fieber, 1851), which were indexed between 1998-2003 (Kulumbetova 1998a(Kulumbetova , b, c, 1999Khamraev 2003) for the Lower Amudarya. These could be rare or migratory species, or are probably misidentified. These five species, shaded in Table 1, have not yet been verified and these records are not used in the distributional and zoogeographical analyses of the group; they are only mentioned in the checklist of the heteropterans found in the Khorezm region and Karakalpakstan.    Khamraev (2003) identified 110 species for the Khorezm, and Kulumbetova (1998aKulumbetova ( , b, c, 1999 62 species for the Republic of Karakalpakstan. The analysis of terrestrial Heteroptera in the Lower Amudarya by Gandjaeva (2007Gandjaeva ( -2020 represented 39 species, which were first studied for the fauna of the Khorezm region and 87 species for the Republic of Karakalpakstan. According to the data, there are currently 149 species of terrestrial Heteroptera recorded in the Lower Amudarya (Fig. 2).
During 2007-2020, 149 species of terrestrial heteropterans were recorded in the Lower Amudarya territory as represented in Table 1.
Recorded species belong to 11 types according to sector ranges, and 28 groups of areas according to belt ranges (Table 3). The Lower Amudarya's hemipteran species were divided into four large groups: Wide Areas, Holarctic Areas, Palaearctic Areas, and Endemic Areas (Fig. 3).
-Broad areas -extend beyond the Holarctic; -Cosmopolitan areas -occur on at least three continents; -Holarctic areas -cover the Palaearctic and the Nearctic region; -Palaearctic areas -cover parts of Europe, Asia, and North Africa; -Nearctic areas -cover North America, Mexico, and Greenland; -The Ethiopia -Trans-Palaearctic -Eastern areas -this complex combines the Palaearctic, Ethiopia and Eastern regions; -Trans-Palaearctic areas -cover the entire Palaearctic; -Super-Atlantic areas -cover from the Atlantic sectors to the Eastern transitional sectors; -The Western areas -cover the part of the Palaearctic Realm from the Eastern Atlantic to the Western Eucontinental sectors; -Pan-Atlantic areas -encompass the Atlantic sector as well as the western subcontinental subsectors; -Pancontinental areas -located from the sub-Atlantic to the eastern continental sectors inclusive; -Narrow Continental areas -cover the Sahara-Gobi Desert area, the Mediterranean and the Irano-Turanian sub-areas.
In the northern part of Uzbekistan, only one species (0.67%) is cosmopolitan. The group of the Holarctic range is characterized by no more than ten species, which constitutes 6.71% of the total, and most species belong to the Palaearctic group, which is most diverse. The group contains 125 species (83.89%), with 38 from the Tethyan-Siberian type constituting 25.50%. Approximately 15 species account for 10.07% of the Irano-Turanian range, while ten species constitute 6.71% of the Euro-Mediterranean-Turanian range. In the Super-Atlantic range, 28 species account for 18.79%, with eight   species making up 5.37% of subboreal and seven species accounting for 4.70% of boreal-subtropical species recorded. Sixteen Trans-Palaearctic species (10.74%) have been recorded, followed by 13 Western (8.72%), 12 North Setian (8.05%), ten Pancontinental (6.71%), and four Pan-Atlantic (2.68%) species. The number of species with Ethiopia-Trans-Palaearctic-Eastern distributions and Narrow Continental is only two for each area or 1.34%. It can be seen that the prevailing part of the group,125 species (83.89%), were found in wider areas of the Holarctic, and 13 are endemic species (8.72%).
The endemics are divided into Chinese-Central Asian, Chinese-Irano-Central Asian, Turkestanian-Northern Turanian, Irano-Turanian-Central Asian, and Turanian (found in Central Asia only). For the assessment of any territory, endemics have a high conservation value since they indicate the distinctive nature of the fauna.

Conclusions
In this study, we collected new 39 species for the Khorezm region and 87 species for the Republic of Karakalpakstan during 2007-2020. In addition, we compare our collections with reports of Khamraev (2003) and Kulumbetova (1998aKulumbetova ( , b, c, 1999 and a total of 154 species (17 families) of terrestrial Heteroptera (Fig. 2, Table 1) were analyzed.
The Heteroptera fauna of Khorezm and Karakalpakstan can be divided into four groups: Cosmopolitan with one species (0.67%); Holarctic, with no more than ten species, or 6.71%; Palaearctic, with most of species (125 species, or 83.89%); and endemic with 13 species, or 8.72%.
An understanding of the fauna is important, as the productivity of crops is currently being negatively impacted by invasive species from neighboring countries. For example, recently we recorded ) the brown marmorated stink bug Halyomorpha halys (Stål, 1855) (Heteroptera: Pentatomidae) from Uzbekistan for the first time. Several adults and immatures were found in the Khorezm and Ferghana provinces. This species is native to East Asia (China, Korea, Japan, and Taiwan) (Rider et al. 2002;Hoebeke and Carter 2003;Rider 2006Rider , 2016 and is a dangerous pest of many agricultural plants. Therefore, more study is required to examine the impacts of dispersion in a northern environment. In the north-western region of Uzbekistan, an increase in the number of invasive Heteroptera is expected, which will require careful monitoring.