2urn:lsid:arphahub.com:pub:45048D35-BB1D-5CE8-9668-537E44BD4C7Eurn:lsid:zoobank.org:pub:91BD42D4-90F1-4B45-9350-EEF175B1727AZooKeysZK1313-29891313-2970Pensoft Publishers10.3897/zookeys.1156.101072101072Research ArticleCarabidaeBiodiversity & ConservationSystematicsAmericasRe-collected after 55 years: a new species of Bembidion (Coleoptera, Carabidae) from CaliforniaMaddisonDavid R.david.maddison@science.oregonstate.eduhttps://orcid.org/0000-0002-7152-38241SproulJohn S.https://orcid.org/0000-0002-6747-35372WillKiplinghttps://orcid.org/0000-0002-7056-90113Department of Integrative Biology, Oregon State University, Corvallis, OR 97331, USAOregon State UniversityCorvallisUnited States of AmericaDepartment of Biology, University of Nebraska Omaha, Omaha, NE 68182, USAUniversity of Nebraska OmahaOmahaUnited States of AmericaEssig Museum of Entomology, University of California, Berkeley, CA 94720, USAUniversity of CaliforniaBerkeleyUnited States of America
Corresponding author: David R. Maddison (david.maddison@oregonstate.edu)
Academic editor: Borislav Guéorguiev
202327032023115687106C03D4908-7A48-56FD-A240-47844F4DE8061B321F54-0511-4933-9C86-9153655F0EA42701202305032023David R. Maddison, John S. Sproul, Kipling WillThis 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.http://zoobank.org/1B321F54-0511-4933-9C86-9153655F0EA4
A new species of the carabid beetle genus Bembidion Latreille is described from the Central Valley, Los Angeles Basin, and surrounding areas of California. Bembidionbrownorumsp. nov. is a distinctive species, a relatively large member of the subgenus Notaphus Dejean, and within Notaphus a member of the B.obtusangulum LeConte species group. It has faint spots on the elytra and a large, convex, rounded prothorax. Of the 22 specimens from 11 localities, all but one were collected more than 55 years ago. Although the collection of the holotype in 2021 at UV light suggest the species is still extant, the lack of other recent specimens suggests the species may have a more restricted distribution than in the past, and its populations may be in decline.
Maddison DR, Sproul JS, Will K (2023) Re-collected after 55 years: a new species of Bembidion (Coleoptera, Carabidae) from California. ZooKeys 1156: 87–106. https://doi.org/10.3897/zookeys.1156.101072
Introduction
Our knowledge of the North American carabid (ground beetle) fauna has benefitted from many decades of significant study and publication (e.g., Hatch 1953; Lindroth 1961–1969; Ball and Bousquet 2000; Bousquet 2012). However, the carabid fauna of the western and southern regions of the continent remains understudied, with distributional ranges, habitats, and life histories of the carabids in those regions still poorly documented and new species still to be discovered and described. To fill this knowledge gap, we have been sampling carabids in the western United States and Canada, frequently targeting areas that appear to have been little sampled.
With about 275 species described from the USA and Canada, Bembidion Latreille is the largest genus of carabid beetles in the region (and the world), and one of the groups most likely to contain undiscovered taxa (e.g., Maddison and Cooper 2014; Sproul and Maddison 2017a; Maddison 2020). These are small beetles, with adults of most species ranging between 3 and 6 mm in length. The majority of species live along the edges of bodies of water, from ocean shores and estuarian areas to pond shores and marshes, river and creek shores, and high-elevation snow fields, but some species are associated with grasslands, alpine meadows, and other areas far from open water. California has the richest fauna in North America, with over 120 species known.
Although within an hour’s drive of the major metropolitan center of Sacramento, many parts of Colusa County, California remain unsampled and little represented in major California entomology collections. Most of the land in the county is privately owned and used for agricultural production, which limits opportunities for access and sampling. Somewhat serendipitously, access and permission to collect was obtained for a ranch, known locally as “Mountain House,” in Colusa County. Over the course of two years, periodic sampling was conducted to determine the diversity of carabid beetles on the property.
Among the many insects sampled, a single specimen of Bembidion stood out as very distinctive (Fig. 1). It was somewhat similar in overall appearance to Bembidionmormon Hayward, B.obtusangulum LeConte, and B.callens Casey, all members of the subgenus Notaphus Dejean, but the specimen’s morphological characteristics were unusual enough that it seemed likely that it belonged to a previously unknown species. Results of analyses of DNA sequence data from the specimen provided additional evidence that it was a new species.
The discovery of this single specimen motivated a search in major carabid collections in California for additional specimens. Only 21 additional specimens were located, all of which were collected more than 55 years ago. The distribution of specimens suggests this was a widespread species, but the lack of recently collected specimens suggests it may now be more restricted in distribution. Given the prospect of a declining and potentially threatened species, we felt it urgent to describe this species to spur the search for additional populations, and prompt research to better understand the species.
Materials and methods
Members of Bembidion were examined from the collections listed below. Each collection’s listing begins with the code used in the text.
BMEC Bohart Museum of Entomology, University of California, Davis, USA;
CASCalifornia Academy of Sciences, San Francisco, USA;
CSAC California State Arthropod Collection, Sacramento, USA;
EMECEssig Museum Entomology Collection, University of California, Berkeley, USA;
NMNHNational Museum of Natural History, Washington, DC, USA;
OSACOregon State Arthropod Collection, Oregon State University, Corvallis, USA.
Morphological methods
General methods of specimen preparation for morphological work, and terms used, follow Maddison (1993, 2008). Genitalia were prepared, after dissection from the body, by treatment in 10% KOH at 65 °C for 10 minutes followed by multi-hour baths of distilled water, 5% glacial acetic acid, distilled water, and finally 100% ethanol. Male genitalia were then mounted in Euparal between two small coverslips attached to archival-quality heavyweight watercolor paper, and, once dried, pinned beneath the specimen.
Photographs of entire beetles, as well as the head and pronotum pictures, were taken with a Leica M165C dissecting scope and a Sony NEX-7 camera, and of male genitalia with a Leica DM5500B compound microscope and DMC425C camera. Microsculpture photographs were taken with a DMC425C camera attached to a DM5500B compound scope equipped with an X-Cite 110LED light source, which provides co-axial illumination, and a 20× epi-illumination objective lens. For all photographs of specimens or body parts, a stack of images from different focal positions was merged using the PMax procedure in Zerene Systems’s Zerene Stacker; the final images thus potentially have some artefacts caused by the merging algorithm. Measurements were made using Leica Application Suite v. 4.9 from images acquired using either a Leica Z6 Apo lens and DMC4500 camera or a Leica DM5500B compound microscope and DMC425C camera.
Taxon sampling for DNA studies
We obtained new DNA sequence data for the holotype of Bembidionbrownorum sp. nov. and 13 specimens of related species of Bembidion. These new data were combined with previously published data from six additional specimens (Maddison 2012; Sproul and Maddison 2017b). As Bembidionflohri Bates, B.mormon, B.callens, and B.obtusangulum appear to be the closest relatives of B.brownorum based upon a more extensive sampling of Bembidion (Maddison unpublished), we focused our sampling on those species, and included three additional species (B.obtusidens Fall, B.scudderi LeConte, and B.consimile Hayward) as outgroups (Tables 1, 2). All voucher specimens are deposited in OSAC except for the holotype of B.brownorum (deposited in EMEC) and the paralectotype of B.callens (specimen 4939, deposited in NMNH as specimen USNM.Ent.01114823).
Sampling of members of Bembidion (Notaphus) for DNA-based study. Four-digit numbers under “#” are D.R. Maddison DNA voucher numbers, and an abbreviation for state or province of capture under “Loc”; further information on the newly sequenced specimens is given in Table 2. Other entries are GenBank accession numbers. Newly acquired sequences are those with accession numbers beginning with “OQ”.
#
Loc
28S
COI
CAD
Topo
Outgroups
B.obtusidens
2042
KY246703
KY246743
KY246784
KY246824
B.scudderi
1471
OQ286105
OQ284076
OQ288589
OQ288575
B.consimile
2506
OQ286106
OQ284077
OQ288590
OQ288576
obtusangulum group
B.flohri
3049
AB
KY246708
KY246749
KY246789
KY246830
B.flohri
3046
OR
KY246707
KY246748
KY246788
KY246829
B.flohri
1753
NV
JN170340
JN171035
JN170807
JN171216
B.flohri
3061
UT
KY246709
KY246750
KY246790
KY246831
B.flohri
5234
NM
OQ286107
OQ284078
OQ288591
OQ288577
B.mormon
3044
OR
OQ286110
OQ284081
OQ288594
OQ288580
B.mormon
2142
UT
OQ286111
OQ284082
OQ288595
OQ288581
B.mormon
3045
UT
OQ286112
OQ284083
OQ288596
OQ288582
B.mormon
4977
NV
OQ286109
OQ284080
OQ288593
OQ288579
B.mormon
2039
CA
OQ286108
OQ284079
OQ288592
OQ288578
B.obtusangulum
2051
AB
JN170397
MF616907
JN170869
MF616774
B.obtusangulum
3151
AB
OQ286113
OQ284084
OQ288597
OQ288583
B.obtusangulum
3594
CO
OQ286115
OQ284086
OQ288599
OQ288585
B.obtusangulum
3043
CA
OQ286114
OQ284085
OQ288598
OQ288584
B.callens
4936
AZ
OQ286116
OQ284087
OQ288600
OQ288586
B.callens
4939
AZ
OQ286117
OQ284088
OQ288601
OQ288587
B.brownorum
5864
CA
OQ286118
OQ284089
OQ288602
OQ288588
Locality information for specimens of Bembidion (Notaphus) analyzed for DNA. Four-digit numbers under “#” are D.R. Maddison DNA voucher numbers.
Species
#
Locality
B.obtusidens
2042
Canada: Alberta: Burbank, junction of Red Deer and Blindman Rivers, 52.3542°N, 113.7556°W
B.scudderi
1471
Canada: Alberta: Bow River at highway 36, 50.246°N, 112.077°W
Canada: Alberta: Birch Lake, 640 m, 53.362°N, 111.5231°W
B.flohri
3046
USA: Oregon: Harney Co., Harney Lake, NE corner, 1237 m, 43.2750°N, 119.0902°W
B.flohri
1753
USA: Nevada: Lyon Co., Carson River near Weeks, 390 m, 39.2866°N, 119.2778°W
B.flohri
3061
USA: Utah: Salt Lake Co., Great Salt Lake Marina, 1280 m, 40.7482°N, 112.1856°W
B.flohri
5234
USA: New Mexico: Torrance Co., Laguna del Perro, 1861 m, 34.6003°N, 105.9252°W
B.mormon
3044
USA: Oregon: Harney Co., 00 Ranch Road NW Harney Lake, 1240 m, 43.2804°N, 119.1976°W
B.mormon
2142
USA: Utah: Salt Lake Co., Great Salt Lake Marina, 390 m, 40.7482°N, 112.1856°W
B.mormon
3045
USA: Utah: Salt Lake Co., Great Salt Lake Marina, 1280 m, 40.7482°N, 112.1856°W
B.mormon
4977
USA: Nevada: Mineral Co., Walker Lake, Twenty Mile Beach, 1200 m, 38.7503°N, 118.7577°W
B.mormon
2039
USA: California: Inyo Co., Owens Lake, 1100 m, 36.4684°N, 117.8585°W
B.obtusangulum
2051
Canada: Alberta: Kenilworth Lake, 10.vi.1993. DRM 93.054
B.obtusangulum
3151
CANADA: Alberta: High Level, 330 m, 58.5073°N, 117.1385°W
B.obtusangulum
3594
USA: Colorado: Alamosa Co., Alamosa NWR, 2292 m, 37.4435°N, 105.7722°W
B.obtusangulum
3043
USA: California: Mono Co., Mono Lake, 1940 m, 37.97780°N, 119.13000°W
B.callens
4936
USA: Arizona: Coconino Co., Havasu Indian Reservation, Havasu Springs, 36.2176°N, 112.6871°W
B.callens
4939
USA: Arizona: Tucson
B.brownorum
5864
USA: California: Colusa Co. Antelope Valley, Freshwater Creek, 39.13841°N, 122.34621°W
DNA sequencing
Genes studied, and abbreviations used in this paper, are: 28S: 28S ribosomal DNA (D1–D3 domains); COI: cytochrome c oxidase subunit I; CAD: part 4 of carbamoyl phosphate synthetase domain of the rudimentary gene; Topo: topoisomerase I.
For specimens collected into 95–100% ethanol (all but the paralectotype of B.callens DNA4939), DNA was extracted using a Qiagen DNeasy Blood and Tissue Kit. Fragments for the four genes were amplified using the Polymerase Chain Reaction on an Eppendorf Mastercycler Pro Thermal Cycler, using TaKaRa Ex Taq and the basic protocols recommended by the manufacturers. Primers and details of the cycling reactions used are given in Maddison (2012) and Maddison and Cooper (2014). The amplified products were then cleaned, quantified, and sequenced at the University of Arizona’s Genomic and Technology Core Facility using a 3730 XL Applied Biosystems automatic sequencer. Assembly of multiple chromatograms for each gene fragment and initial base calls were made with Phred (Green and Ewing 2002) and Phrap (Green 1999) as orchestrated by Mesquite’s Chromaseq package (Maddison and Maddison 2021a, c), with subsequent modifications by Chromaseq and manual inspection. Multiple peaks at a single position in multiple reads were coded using IUPAC ambiguity codes.
DNA extraction and sequencing of the paralectotype of Bembidioncallens DNA4939 followed Sproul and Maddison (2017b). In brief, DNA in that specimen was extracted using the Qiagen QIAmp Micro Kit (using the standard protocol with carrier RNA added), with dual-index libraries prepared using the NEBNext DNA Ultra II kit (New England BioLabs), which were then sequenced on an Illumina HiSeq 3000, multiplexed on a 150-base paired-end lane at the Oregon State University Center for Quantitative Life Sciences. No other members of subgenus Notaphus were included on that lane. Approximately 66 million reads were obtained for the sample. Reads were processed in CLC Genomics Workbench (CLCGW) v. 22.0. Reads were trimmed to eliminate low-quality ends (limit = 0.000316, corresponding to a quality score of 35) and to remove adapter sequences. The number of reads left after trimming was approximately 46 million. De novo assemblies were generated using CLCGW from paired, trimmed reads using an automatic word and bubble size, with the minimum contig length set to 200. The de novo assemblies were converted to BLASTable databases using NCBI’s makeblastdb tool and BLASTed using Mesquite’s (Maddison and Maddison 2021c) local BLAST tool (1E-30 as the e-value cutoff for nuclear protein-coding genes, and 1E-100 the cutoff for COI and 28S) using as query sequences the sequences of the four target genes from B.mormon DNA3045. For each gene, only one contig was returned; these hits were BLASTed to NCBI’s GenBank, and in all cases returned Bembidion as the top match.
Newly acquired sequences are all of “genseq-4” (Chakrabarty et al. 2013), except for those of the holotype of B.brownorum (specimen 5864) which are “genseq-1”, and those of the paralectotype of B.callens (specimen 4939), which are “genseq-2”.
Alignment and data exclusion
COI, CAD, and Topo were easily aligned by eye, as there were no insertions or deletions (indels) evident in the sampled sequences. Alignment of 28S was conducted in MAFFT v. 7.130b (Katoh and Standley 2013) using the L-INS-i search option and otherwise default parameter values. In general, no sites were excluded from analyses, except at the 5’ and 3’ ends of the alignments; those regions were excluded, as they were mostly missing data, containing data from only a small fraction of the samples because of variation in the length of the sequences that were obtained.
Phylogenetic analyses
A maximum-likelihood (ML) analysis was conducted for each gene individually using IQ-TREE v. 2.1.3 (Nguyen et al. 2015), as orchestrated by Mesquite’s Zephyr package (Maddison and Maddison 2021b, c). The ModelFinder feature within IQ-TREE (Kalyaanamoorthy et al. 2017) was used to find the optimal character evolution models. The MFP model option was used for 28S, and the TESTMERGE option for protein-coding genes. The TESTMERGE option sought the optimal partition of sites, beginning with the codon positions in different parts. Fifty searches were conducted for the ML tree for each matrix analyzed. In addition, analyses of a matrix formed by concatenation of all four gene fragments were conducted, with the TESTMERGE option also being used, beginning with each codon position for each gene as a separate part (thus, the analysis began allowing for up to 10 parts: three for each of the three protein-coding genes, and one for 28S). Fifty searches were conducted for the ML tree. For standard, non-parametric bootstrap analysis of the concatenated data, 500 replicates were used.
Data availability
Sequences of the studied genes have been deposited in GenBank with accession numbers OQ284076 to OQ284089, OQ286105 to OQ286118, and OQ288575 to OQ288602. Files containing the untrimmed gene sequences for each specimen as well as the inferred trees for each gene have been deposited in Dryad (data available from the Dryad Digital Repository at https://doi.org/10.6078/D17416.
ResultsMolecular and phylogenetic results
The single specimen of Bembidionbrownorum sequenced is quite distinctive in DNA sequences of 28S, COI, and Topo, and clearly outside the bounds of sequence variation in the other species sampled. This is evident both by the gene trees (Fig. 2) and by the details of variation. Bembidionbrownorum differs from all specimens of the morphologically most similar species, B.mormon, at 13 bases in 28S, 44 bases in COI (6.7% divergence), two amino acids in CAD, and one amino acid in Topo. It differs from B.callens, which appears as a member of its sister group, at seven bases in 28S, 28 bases in COI (4.3% divergence), and three amino acids in CAD, and from the other member of its sister group, B.obtusangulum, at nine bases in 28S, and 33 bases in COI (5.0% divergence).
Maximum-likelihood trees of the Bembidionobtusangulum group for four individual genes as well as the concatenated matrix. Scale bars: 0.01 nucleotide substitutions per nucleotide site, as reconstructed by IQ-TREE. Outgroups not shown; in all single-gene and concatenated analyses, the five species shown here formed a clade, with a bootstrap value of 100% in the concatenated analysis.
https://binary.pensoft.net/fig/830107
Three of the genes (28S, COI, and Topo) individually suggest that the nearest relatives of B.brownorum are B.callens and B.obtusangulum; in the ML tree of the concatenated matrix of all four genes, the latter two species form a clade with B.brownorum as its sister group (Fig. 2). The bootstrap value for the concatenated matrix for this sister-group relationship is 68%.
Morphological results
Bembidionbrownorum has a distinctively convex and rounded prothorax (Fig. 3A) in addition to other characteristics that distinguish it from additional members of the subgenus Notaphus, as documented in the Taxonomic Treatment section below.
Habitus of members of the Bembidionobtusangulum species group ABembidionbrownorum, holotype male BBembidionmormon male CBembidioncallens (paralectotype) female DBembidionobtusangulum male. Scale bars: 1 mm.
To accommodate B.brownorum, couplet 169 in Lindroth’s (1963) key can be modified into a triplet as follows (figure numbers refer to those in Lindroth (1963) except as specified):
169
3.5–4.0 mm. Upper surface unmetallic. Prothorax with evident latero-basal carina (fig. 171b)
102. B.nudipenne
–
4.4–5.0 mm. Upper surface unmetallic or only slightly metallic. Latero-basal carina evident, long (this paper, Fig. 4B). Prothorax broad and very convex (this paper, Fig. 1). California
B.brownorum
–
4.3–5.9 mm. Metallic above. Latero-basal carina thin, usually rudimentary, or absent (fig. 187). Prothorax convex
Holotype. Male, in EMEC, herein designated, labeled: “39.13841/−122.34621 USA: California: Colusa Co. Antelope Valley, Freshwater Creek uv light pan trap 133 m. 1.vii.2021 K.Will [Cal2021.vii.1.2]”, “David R. Maddison DNA5864 DNA Voucher” [pale green paper], “HOLOTYPE Bembidionbrownorum Maddison, Sproul, & Will” [partly handwritten, on red paper], “UC Berkeley EMEC 347587” [with matrix code on right side]. Genitalia mounted in Euparal in between coverslips pinned with specimen; extracted DNA stored separately. GenBank accession numbers for DNA sequences of the holotype are OQ284089, OQ286118, OQ288588, and OQ288602.
Paratypes. (13 males, 8 females). “Borax Lake, Lower Lake, Lake Co., Cal. May 14 1922” (2, CAS). “Atwater, Merced Co., Calif 15 Aug 1966” (5, CAS, OSAC). “Wood L., Tulare Co., Calif. Rotary Trap V-22-1947 Norman W. Frazier, EMEC347588” (1, EMEC). “Wood L., Tulare Co., Calif. Rotary Trap V-24-1947 Norman W. Frazier EMEC347589” (1, EMEC). “Redondo, Cal.” (1, CAS). “Pasadena, Cal.” (3, CAS). “San Joaquin Mill Tulare Co., Calif. May 15, 3800 ft” (2, CAS). “Azusa, Cal.” (1, CAS). “Riverside, Cal. F.E. Winters” (1, CAS). “CALIF: Forest Home, San Bernardino Mts, 6000 ft. May” (1, CAS). “Poway, San Diego Co., Cal.” (2, CAS). “S. Cal” (1, CAS).
Type locality of Bembidionbrownorum. USA: California: Colusa Co. Antelope Valley, Freshwater Creek, 39.13841°N, 122.34621°W. Image taken November 2022.
https://binary.pensoft.net/fig/830110Derivation of specific epithet.
The specific epithet brownorum is treated as a noun in the genitive case and refers to Jerry and Anne Brown, former Governor and First Lady of California, respectively. The name is formed in their honor as it was their hospitality and openness to allowing access for research of insects on their ranch, the type locality, which led to the discovery of this species. Additionally, this honors their long commitment to environmentalism and continued efforts in the international climate-change movement.
Diagnosis.
A relatively large Bembidion (Notaphus), superficially similar to B.mormon (with which it has been confused in collections), with which it shares a pale subapical band on the elytra. However, B.brownorum has a much more convex pronotum, giving it an inflated appearance; the pronotum has more rounded sides and is more constricted posteriorly. From B.callens and B.obtusangulum, in addition to the prothorax shape, it is distinguished by presence of pale elytral spots, which those two species lack.
Description
(based upon the holotype and 21 paratypes). Body length 4.4–5.0 mm. Body dark brown or dark reddish brown, with head and pronotum slightly darker than elytra; elytra each with one diffuse pale spot at about the posterior fourth. Legs uniform in color, reddish brown; antennae brown, with first antennomere paler, at least ventrally. Mentum with anterior lateral regions large, with apical portion broadly rounded, not angulate; medial tooth simple (not bifid) with truncate tip; frontal furrows weakly defined, shallow; eyes prominent (Fig. 4A). Prothorax large, notably convex, with sides strikingly rounded such that the width at middle is much greater than the width at the posterior margin, with sides immediately front of hind angle slightly sinuate (Fig. 4B); hind angle slightly obtuse; posterolateral carina well defined, moderately long; posterior region of pronotum slightly rugose. Elytra with lateral bead not prolonged medially at shoulder; all striae complete, striatopunctate, with much smaller punctures in the posterior half. Microsculpture present on most of the dorsal surface of the body except for the disc of the pronotum, which is glossy; evident in both sexes over entire surface of elytra, consisting of sculpticells that are slightly transverse, more deeply engraved in females (Fig. 6B) than in males (Fig. 6A); female elytra thus matte. Pronotum with two lateral setae on each side; elytron with two setae in third interval. Aedeagus (Fig. 6C) typical for a member of subgenus Notaphus.
Microsculpture and aedeagus of BembidionbrownorumA elytral microsculpture around seta ed3 of holotype male B elytral microsculpture around seta ed3 of a female from Woodlake C aedeagus of holotype male. Scale bars: 100 µm.
All 18 specimens examined for wing condition are macropterous. The capture of two specimens from Woodlake in a rotary trap (Winkler 1949) and the capture of the holotype at a UV light both suggest that these beetles can fly.
Geographic variation.
None noted.
Geographic distribution.
Central Valley, Los Angeles Basin, and surrounding areas of California (Fig. 7). Two of the localities on the map are marked as uncertain: those labeled as from Forest Home and Redondo. The Forest Home locality is at much higher elevation than all other specimens (6000 ft). Based upon the labeling on other specimens from the F.E. Winters collection, the hand-written label attached to this specimen appears not to be an original label, and we have doubts about the validity of the data on the label. We have some doubts about the locality for the specimen labeled “Redondo”, as there are at least seven localities in California that include “Redondo” in the name (USGS Geographic Names Information System, https://edits.nationalmap.gov/apps/gaz-domestic/public/search/names). An additional locality, “San Joaquin Mill Tulare Co., Calif 3800 ft” was not mapped as we could not determine the site with any certainty.
Geographic distribution of Bembidionbrownorum in California. The locality indicated with a star is the type locality. The two localities indicated by gray dots are uncertain or doubtful. Darker gray areas in the base map represent higher elevations.
https://binary.pensoft.net/fig/830112Habitat.
The only specimen with detailed collecting data including an exact locality is the holotype. Because it was collected at a UV light, the specimen was not found in its natural microhabitat, and we do not know how far it had flown from a suitable habitat. However, the type locality might provide some hints about possible habitat of the species. The type locality lies on the east side of Antelope Valley in the northern part of the Cortina Ridge, which marks the western edge of the Colusa Basin region of the Sacramento Valley. The ridge is formed of tilted sandstone beds, mudstone, and siltstone formed from the eroded sediments of the Sierran–Klamath terrane. As members of subgenus Notaphus are almost universally found at the edges of bodies of water (with exceptions for some species found at high elevation), we expect B.brownorum to live on lake, pond, marsh, river, or creek shores. The UV light was set up next to Freshwater Creek (Fig. 5), which might be the habitat of the specimen. Freshwater Creek cuts through Cortina Ridge; its bed is composed of consolidated claystone and lenses of poorly hardened conglomerate, sandstone, and siltstone. The stream is somewhat trellis-like, with persistent pools, due to the presence of minor ridges of erosion-resistant materials. The current dominant vegetation consists of grasses, cattails, willows, and rushes near the stream. Sparsely set oaks line the stream edge and lateral drainages. Water is persistent and flows on the surface in portions of the stream throughout the year. Evaporation along the stream margin intermittently creates a hardened crust of white mineral deposits that often overlays a black, highly organic mud in depositional stretches. Narrow, steep-sided sections of the stream have banks composed of exfoliating claystone and mud from eroded topsoil. The adjacent land was historically used for crop production, e.g., barley, but the land and water has primarily been used for cattle ranching. Both the stream bed and adjacent area show the impact of many years of cattle grazing. There is an historical account of beaver damming (J. Brown pers. com.) but there is presently no impact of this event. There is no evidence that the water flow has been artificially dammed, channelized, or diverted in the collection area. As such, this stretch of Freshwater Creek represents a relatively unaltered, natural, perennial source of surface water—unusual in the Central Valley and adjacent foothills of California. However, we consider evidence for B.brownorum being a stream-shore species very weak, as it is based upon only one specimen which might have flown in from some distance.
The other known localities do not clearly suggest a specific habitat, nor do the known localities of related species. Bembidionbrownorum localities include a lake with sodium borate deposits (Borax Lake, Lake County), a city with a lake with extensive, flat shores (Bravo Lake in Woodlake), and a site near the Pacific Ocean that once had a salt lake (Redondo). At least the latter two are habitats similar to the saline, pond and lake shore habitats frequented by B.obtusangulum and B.mormon, near relatives of B.brownorum. The specimen labeled as from 6000 feet elevation at Forest Home, San Bernardino Mts (presumably around 34.083°N, 116.893°W) suggest instead a less saline, creek shore habit, but we doubt the veracity of that label (see above). The only specimen of the related B.callens with known habitat data is a specimen collected by Larry Stevens in gravel around the calcium-carbonate-rich waters of Havasu Springs, Arizona, at 36.2176°N, 112.6871°W (Larry Stevens pers. comm. 2022).
Discussion
Much attention has recently been drawn to the apparent decline of insect populations (Sánchez-Bayo and Wyckhuys 2019; Wagner 2020; Wagner et al. 2021). Given the many, significant changes brought about by human activities, which range in scale from local and ephemeral to global and long-term, substantial changes in insect abundance and species assemblages are not surprising. Even in the absence of apparent changes in measures like species richness, insect assemblages may be homogenized with increases in generalist species and species that can take advantage of human habitat alterations (Ball-Damerow et al. 2014). Among carabid beetles, species decline and apparent extinction have been recently documented (Kotze and O’Hara 2003; Knisley and Fenster 2005; Brandmayr et al. 2009), and a number of traits have been hypothesized as being linked to decline and extinction risk (Kotze and O’Hara 2003; Nolte et al. 2019). Examples of these risk-linked traits are (1) habitat specialization, (2) small distributional range, (3) large body size, and (4) being either monomorphic macropterous or brachypterous. Bad luck (sensu Samways 2006) also plays a role, in that narrow habitat requirements or restricted ranges may coincide with human land use priorities that impact beetles. Among carabid beetles, there are notable examples of unlucky species from California. For example, the southern subspecies of the Golden Bear Harpaline (Dicheirusdilatatusangulatus Casey) is hypothesized to have been impacted by annual fire break disturbance (Noonan 1968), transformation of seasonal wetlands to agricultural production that reduced available habitat significantly impacted the Delta Green Ground Beetle (Elaphrusviridis Horn) (Arnold and Kavanaugh 2021), and urban development and general habitat degradation have ongoing effects on the Ohlone Tiger Beetle (Cicindelaohlone Freitag & Kavanaugh) (Knisley and Arnold 2013).
It is likely that B.brownorum is yet another unlucky carabid beetle species. After our initial collection and recognition of B.brownorum we searched relevant collections for additional specimens. The small number of specimens located were only found in the EMEC and CAS collections, both with significant quantities of older material, including substantial holdings from pre-1950 (https://essig.berkeley.edu/museum-history/, https://www.calacademy.org/scientists/entomology-information-page#history). Despite having considerable and important carabid beetle holdings, no specimens were found in the CSAC and BMEC collections, which almost exclusively have specimens collected after 1970. Prior to 2021, the most recent specimen is from Atwater, California, collected in 1966. The only other specimens with an explicit date are from the 1940s. The undated specimens have labels in styles that suggest they are at least as old or older than those with dates. For example, specimens of the F.E. Winters collection in CAS and EMEC are typically from collecting events in the early twentieth century, up to about 1930. Such a long gap in sampling may be indicative of species deterioration but can also be the result of a lack of sampling (i.e., “Wallacean extinction” of Ladle and Jepson 2008) or the lack of available taxonomic expertise (also a resource in significant decline). Various factors can affect repeat collection of a given species, such as range size, collecting effort, habitat access, and collectability (Ladle et al. 2011).
Bembidionbrownorum’s large range (Fig. 7) and small body size suggest that it should be resistant to decline, but its apparent monomorphic macroptery could be a risk factor (Kotze and O’Hara 2003; Scheffers et al. 2011; Nolte et al. 2019). Additionally, given its large range and that these beetles are attracted to lights, frequent collection would be expected even though its small size might cause it to be missed during visual-search collecting by general collectors and despite habitat access issues in California. Other species collected abundantly in light traps in 2021 from Colusa County, such as Stenolophus (Stenolophus) anceps LeConte, Stenolophus (Stenolophus) limbalis LeConte, and Pseudaptinus (Pseudaptinus) tenuicollis (LeConte), Bembidion (Trepanedoris) connivens (LeConte), Bembidion (Furcacampa) timidum (LeConte), and Bembidion (Notaphus) approximatum (LeConte), are represented in all the collections we surveyed, in very large numbers, and across the full distributional and temporal range. These observations suggest that B.brownorum has likely experienced a significant decline in population numbers, and that the lack of recently collected specimens is not simply because it has been missed or overlooked by collectors.
Though details on the microhabitat are unknown, it seems probable that habitat specialization and the degradation of that habitat led to this species’ decline. At a very general level, most of the locations at which B.brownorum was historically collected presently have no apparent, natural habitat, and are entirely highly developed (Atwater, Woodlake, Redondo [Beach], Pasadena, and Azusa) or are largely developed with little potential habitat (Riverside and Poway). Perhaps the Borax Lake region, which is only 33 km southwest of the type locality, holds the best odds for a persistent population. In addition, lakes near previous localities may also harbor populations (e.g., Bravo Lake, within 4 km of the Woodlake collection site, or East Park Reservoir, about 25 km NNE of the type locality, or Indian Valley Reservoir, about 17 km W of the type locality).
The recent collection of B.brownorum raises our hopes that the species persists in more locations, and we encourage efforts to sample for it, but we are concerned that the species still has the potential to disappear forever. Rediscovery or re-collection does not mean a species is doing well. As pointed out by Scheffers et al. (2011), “88% of rediscovered [vertebrate] species are currently threatened” and declining abundance leads to declining detectability, making the job of conservation even harder. Will populations of this, and other imperiled species, be located before the many sources of disturbance (e.g., invasive species, habitat loss, pesticide exposure, and climate change) drive them to extinction?
Acknowledgements
We thank Jerry and Anne Brown for allowing access to their property and encouraging collecting and research activities. We thank collection personnel of the entomological collections for allowing us to examine their holdings and borrow materials, in particular Christopher Grinter (CAS), Lynn Kimsey (BMEC), and Martin Hauser (CSAC). We thank Larry Stevens (Springs Stewardship Institute) for sending the specimen of Bembidioncallens from Havasu Springs. For performing some of the PCR reactions on which the DNA sequence data in this paper is based, we thank Tiana S.L. Week, Danielle L. Mendez, Estany Campbell-Dunfee, and Joseph J. Dubie. We thank Borislav Guéorguiev, Luca Toledano, David H. Kavanaugh, and an anonymous reviewer for their thoughtful reviews of the manuscript.
This project was supported by the Harold E. and Leona M. Rice Endowment Fund at Oregon State University.
ReferencesArnoldRAKavanaughDH (2021) Geographic distribution and habitat characterization of the threatened Delta Green Ground Beetle, Elaphrusviridis Horn, 1878 (Coleoptera: Carabidae), in the Jepson Prairie Region of Solano County, California, USA.75(3): 519–530. https://doi.org/10.1649/0010-065X-75.3.519BallGEBousquetY (2000) Carabidae Latreille, 1810. In: ArnettRHThomasJr MC (Eds) American Beetles (Vol., 32–132.Ball-DamerowJEM’GonigleLKReshVH (2014) Changes in occurrence, richness, and biological traits of dragonflies and damselflies (Odonata) in California and Nevada over the past century.23(8): 2107–2126. https://doi.org/10.1007/s10531-014-0707-5BousquetY (2012) Catalogue of Geadephaga (Coleoptera, Adephaga) of America, north of Mexico.245: 1–1722. https://doi.org/10.3897/zookeys.245.3416BrandmayrPPizzolottoRColombettaGZettoT (2009) In site extinction of carabid beetles and community changes in a protected suburban forest during the past century: The “Bosco Farneto” near Trieste (Italy).13(2): 231–234. https://doi.org/10.1007/s10841-008-9161-6ChakrabartyPWarrenMPageLMBaldwinCC (2013) GenSeq: An updated nomenclature and ranking for genetic sequences from type and non-type sources.346: 29–41. https://doi.org/10.3897/zookeys.346.5753GreenP (1999) Phrap. Version 0.990329. http://phrap.orgGreenPEwingB (2002) Phred. Version 0.020425c. http://phrap.orgHatchMH (1953) University of Washington, Seattle, 340 pp.KalyaanamoorthySMinhBQWongTKFvon HaeselerAJermiinLS (2017) ModelFinder: Fast model selection for accurate phylogenetic estimates.14(6): 587–589. https://doi.org/10.1038/nmeth.4285KatohKStandleyDM (2013) MAFFT multiple sequence alignment software version 7: Improvements in performance and usability.30(4): 772–780. https://doi.org/10.1093/molbev/mst010KnisleyCBArnoldRA (2013) Biology and conservation of Cicindelaohlone Freitag and Kavanaugh, the endangered Ohlone Tiger Beetle (Coleoptera: Carabidae: Cicindelinae). I. Distribution and natural history.67(4): 569–580. https://doi.org/10.1649/0010-065X-67.4.569KnisleyCBFensterMS (2005) Apparent extinction of the tiger beetle, Cicindelahirticollisabrupta (Coleoptera: Carabidae: Cicindelinae).59(4): 451–458. https://doi.org/10.1649/799.1KotzeDJO’HaraRB (2003) Species decline–But why? Explanations of carabid beetle (Coleoptera, Carabidae) declines in Europe.135(1): 138–148. https://doi.org/10.1007/s00442-002-1174-3LadleRJJepsonP (2008) Toward a biocultural theory of avoided extinction.1(3): 111–118. https://doi.org/10.1111/j.1755-263X.2008.00016.xLadleRJepsonPMalhadoACMJenningsSBaruaM (2011) The causes and biogeographical significance of species’ rediscovery.3(3): 111–118. https://doi.org/10.21425/F5FBG12432LindrothCH (1963) The ground-beetles (Carabidae, excl. Cicindelinae) of Canada and Alaska. Part 3. Opuscula Entomologica (Supplementum 24): 201–408.LindrothCH (1961–1969) The ground-beetles (Carabidae, excl. Cicindelinae) of Canada and Alaska. Parts 1–6. Opuscula Entomologica Supplementum 20, 24, 29, 33, 34, 35: 1–1192.MaddisonDR (1993) Systematics of the Holarctic beetle subgenus Bracteon and related Bembidion (Coleoptera: Carabidae).153: 143–299.MaddisonDR (2008) Systematics of the North American beetle subgenus Pseudoperyphus (Coleoptera: Carabidae: Bembidion) based upon morphological, chromosomal, and molecular data.77(1): 147–193. https://doi.org/10.2992/0097-4463-77.1.147MaddisonDR (2012) Phylogeny of Bembidion and related ground beetles (Coleoptera: Carabidae: Trechinae: Bembidiini: Bembidiina).63(3): 533–576. https://doi.org/10.1016/j.ympev.2012.01.015MaddisonDR (2020) Shards, sequences, and shorelines: Two new species of Bembidion from North America (Coleoptera, Carabidae).1007: 85–128. https://doi.org/10.3897/zookeys.1007.60012MaddisonDRCooperKW (2014) Species delimitation in the ground beetle subgenus Liocosmius (Coleoptera: Carabidae: Bembidion), including standard and next-generation sequencing of museum specimens.172(4): 741–770. https://doi.org/10.1111/zoj.12188MaddisonDRMaddisonWP (2021a) Chromaseq: a Mesquite package for analyzing sequence chromatograms. Version 1.53. http://chromaseq.mesquiteproject.orgMaddisonDRMaddisonWP (2021b) Zephyr: a Mesquite package for interacting with external phylogeny inference programs. Version 3.20. http://zephyr.mesquiteproject.orgMaddisonWPMaddisonDR (2021c) Mesquite: a modular system for evolutionary analysis. Version 3.70. http://www.mesquiteproject.orgNguyenL-TSchmidtHAvon HaeselerAMinhBQ (2015) IQ-TREE: A fast and effective stochastic algorithm for estimating maximum-likelihood phylogenies.32(1): 268–274. https://doi.org/10.1093/molbev/msu300NolteDBoutaudEKotzeDJSchuldtAAssmannT (2019) Habitat specialization, distribution range size and body size drive extinction risk in carabid beetles.28(5): 1267–1283. https://doi.org/10.1007/s10531-019-01724-9NoonanGR (1968) A revision of the genus Dicheirus Mannerheim 1843.33: 281–304.SamwaysMJ (2006) Insect extinctions and insect survival.20(1): 245–246. https://doi.org/10.1111/j.1523-1739.2006.00349.xSánchez-BayoFWyckhuysKAG (2019) Worldwide decline of the entomofauna: A review of its drivers.232: 8–27. https://doi.org/10.1016/j.biocon.2019.01.020ScheffersBRYongDLHarrisJBCGiamXSodhiNS (2011) The world’s rediscovered species: Back from the brink? PLoS ONE 6(7): e22531. https://doi.org/10.1371/journal.pone.0022531SproulJSMaddisonDR (2017a) Cryptic species in the mountaintops: species delimitation and taxonomy of the Bembidionbreve species group (Carabidae: Coleoptera) aided by genomic architecture of a century-old type specimen.183: 556–583. https://doi.org/10.1093/zoolinnean/zlx076SproulJSMaddisonDR (2017b) Sequencing historical specimens: Successful preparation of small specimens with low amounts of degraded DNA.17(6): 1183–1201. https://doi.org/10.1111/1755-0998.12660WagnerDL (2020) Insect declines in the Anthropocene.65(1): 457–480. https://doi.org/10.1146/annurev-ento-011019-025151WagnerDLGramesEMForisterMLBerenbaumMRStopakD (2021) Insect decline in the Anthropocene: Death by a thousand cuts. Proceedings of the National Academy of Sciences of the United States of America 118(2): e2023989118. https://doi.org/10.1073/pnas.2023989118WinklerA (1949) Pierce’s disease investigations.19(7): 207–264. https://doi.org/10.3733/hilg.v19n07p207