A New Genus and Species of Gall-Forming Fordini (Hemiptera: Aphididae) on Rhus wilsonii Hemsl. from Yunnan, China

Simple Summary A new species of aphid, causing the formation of large galls on a sumac species endemic to Yunnan, China, is named and described. Molecular and morphological diagnostic criteria are provided, and digital specimen data made available. Abstract A new species of gall-forming aphid from China, Qiao jinshaensis gen. et sp. nov., is described from Rhus wilsonii Hemsl. Morphological identification and molecular analyses both support the establishment of a new genus. A diagnosis combining morphological and molecular characters from alate viviparae is provided and specimen metadata are published in an open-access and machine-readable format.

Aphid galls were collected for the first time on Rhus wilsonii Hemsl. in Yunnan, China. Their shapes were similar to those formed by some Nurudea Matsumura, 1917 andFloraphis Tsai &Tang, 1946 species, but the morphological identification of the aphids did not correspond to any currently known species. Morphological and molecular analyses were conducted but were not conclusive in assigning the species to any existing genus, thus supporting the establishment of a new one. We here formally establish Qiao jinshaensis gen. et sp. nov. Morphological and molecular diagnostic criteria are used following the protocol in Hébert et al. [8]. Additionally, the specimen collection data are published in a machine-readable format, making them readily accessible for future research.

Field Sampling
Fresh galls were collected in Yunnan, China (28.014 • N, 103.638 • E) on the host plant, Rhus wilsonii, and taken to the lab (see below for full collection data). Aphids were extracted from the galls and immersed in 70% ethanol for slide preparation and 100% ethanol for DNA extraction.

Molecular Analysis
Total genomic DNA was extracted from 20-30 individual aphids collected from a gall using Ezup animal genome DNA extraction kit at Sangon Biotech Co., Ltd., (Shanghai, China), according to the manufacturer's protocol. The standard primer pair EF2 and EF3 [9] were used to amplify the elongation factor 1-alpha (EF1α) gene and HCO2198 and LCO1490 [10] were used to amplify a region of the mitochondrial cytochrome c oxidase subunit 1 (COI) gene. Polymerase chain reaction (PCR) amplification was carried out using standard protocols [11] with annealing temperatures of 56 • C for the EF1α locus and 55 • C for the COI locus. To ensure the accuracy of the sequence, the EF1α target fragment was incised and purified using a gel extraction kit (EZ-10 Column DNA Purification Kit, Bio Basic Inc., Markham, ON, Canada) according to the manufacturer instructions. Purified PCR products were sequenced in both directions on an ABI-3730XL gene sequencer at Sangon Biotech Co., Ltd. (Shanghai, China). The two sequences have been deposited in GenBank (accession numbers OP536221 and OP548621).
Introns in the EF1α sequence were removed in Geneious Prime 2022 software (Biomatters Ltd., Auckland, New Zealand) for analysis. Simple genetic p-distances were calculated with a Clustal Omega multiple alignment [12], as implemented in Geneious, with EF1α and COI sequences from other Rhus-gall aphids (see Table 1 for accession numbers). Simple (single nucleotide) and compound (multiple nucleotides) molecular diagnostic characters were retrieved manually for the COI sequence. Nucleotide positions are in reference to the COI alignment with the Acyrthosiphon pisum (Harris, 1776) mitochondrial genome (accession FJ411411). The tannin content of the new galls was measured by ultraviolet spectrometry [13,14].

Morphological Examination
Fourteen aphids were cleared and slide-mounted in Canada balsam [15]. The identification key of Blackman and Eastop [2], as well as the original published descriptions of other Rhus-gall aphids [16][17][18][19], were used to assess the identity of the new species. Measurements and pictures were taken under brightfield conditions with a Zeiss M2 AxioImager microscope, an AxioCam HRc camera, and Zen 2012 Software, version 1.1.1.0 (Carl Zeiss AG, Oberkochen, Germany). All measurements are in micrometers (µm).
Morphological abbreviations are as follows: BL-body length (measured from the frontal margin of the head to the end of the cauda); BW-basal width; ANT I, II, III, IV, V, Insects 2022, 13, 1104 3 of 11 VI-antennal segments I, II, III, IV, V, VI or their length; PT-processus terminalis of the last antennal segment or its length; BASE-base of the last antennal segment or its length; URS-ultimate rostral segments (IV + V) or their length; LMF-length of the metafemur; LMT-length of the metatibia; WMT-width of the metatibia (measured in the middle); LMTS-length of the longest setae of the metatibia; HT I-first segment of the hind tarsus or its length (measured on the ventral side); HT II-second segment of the hind tarsus or its length.

Molecular Analysis
The COI genetic p-distances between the new species and other species of Rhus-feeding Fordini ranged from 9.4% to 12.4%, much higher than the mean 7.3% infrageneric divergence found among aphids in general [20], and within the 9.7-11.3% range of intergeneric divergence we measured between Rhus-feeding Fordini (Table 1). Additionally, the average sequence divergence between the new species and other Rhus-feeding genera was 10.6%, greater than the 9.5% divergence between the other genera excluding the new species. The EF1α sequence divergence between the new species and other Rhus-feeding Fordini ranged from 5.1% to 7.7%. The average EF1α sequence divergence between the new species and Rhus-feeding genera was 6.1%, much higher than that between just the other genera (excluding the new species), which was 3.8%. These data confirm that the new species is genetically distinct, at the generic level, from all other Rhus-galling aphids for which DNA sequence data are available.

Taxonomic Treatment
The genus and species are established together, in accordance with Article 13.

Diagnosis
The new genus can be distinguished from other Rhus-galling aphids by several characteristics. It has six antennal segments compared to five in Nurudea and Schlechtendalia. It differs from Meitanaphis Tsai & Tang, 1946, by having a short and oblique stigma on the

Diagnosis
The new genus can be distinguished from other Rhus-galling aphids by several characteristics. It has six antennal segments compared to five in Nurudea and Schlechtendalia. It differs from Meitanaphis Tsai & Tang, 1946, by having a short and oblique stigma on the forewing and three (rarely two) hamuli on the hindwing costa (stigma long and sickleshaped and two (sometimes one) hamuli in Meitanaphis). The numerous ring-like sensoria of Floraphis and Melaphis Walsh, 1867, differentiate them from our new genus, which has large, oblong sensoria. Lastly, Kaburagia has only one large oval sensorium on ANT III-VI, whereas our species has more variation in shapes and numbers of sensoria, with the larger ones on ANT IV-VI enclosing small, sclerotized islands. Thirteen simple and four compound nucleotide characters were unique to our new species when the COI sequence was compared with the other available aphid species causing galls on Rhus (Table 2).

Description
Color. In prepared specimens: Head, antennae, thorax and legs medium-brown ( Figure 2). Genital plate, anal plate, and cauda light brown. Abdomen very light, almost transparent. Abdomen. Marginal and spinal wax glands (Figure 9). Cauda semicircular, length 0.35-0.57 × its BW, bearing three to four setae. Genital plate bearing 24-33 setae, mostly distributed on the apical margin. Spiracles inconspicuous. Siphunculi absent. Measurements presented in Table 3.  Head. Triommatidium distinct (Figure 3). Pale, linear ventral depression from the middle ocellus to the clypeus (Figure 4). Front margin of the head with two setae, which are 1.25-1.96 × the BW of ANT III. There are 5-6 pairs of dorsal setae and 11-13 ventral setae. There are two to four wax glands. Non-sclerotic region at the insertion of the antennae. Rostrum reaching past the front coxae, with URS 0.55-0.69 × HT II and bearing two accessory setae. Antennal tubercles undeveloped. Antennae are six-segmented ( Figure 5). ANT 0.24-0.32 × BL. ANT III and V subequal in length; ANT VI longest. Short PT, 0.09-0.16 × BASE with four apical setae. Sensoria irregular in shape and numbers. ANT IV-V-VI each with one large sensorium occupying most of the length of the segment, enclosing small, scattered islands of cuticle and sometimes accompanied by a smaller round or oval secondary sensorium. Secondary sensoria (between one and four) of ANT III with more shape variation, either as small or large transverse bands, with or without sunken grooves, round or oval. They can also vary between the two antennae of the same specimen.         Thorax. Wax glands present. Mesosternal furca 'Y'-shaped with a well-developed stem ( Figure 6). Trochanter and femur fused (Figure 7). LMF 3.86-4.69 × ANT III. Legs slender with short and pointed setae. LMT 0.28-0.37 × BL and LMTS 0.47-0.60 × WMT. HT I triangular, 0.25-0.36 × HT II (Figure 8). First tarsal chaetotaxy: 3-4-4, with distal margin forming small spines. Forewing with two cubital veins well separated at the base, media simple with basal half obsolete, stigma short and oblique, veins fading at their apical extremity (Figure 2). Hindwing with 3 (rarely 2) hamuli on the costal margin and two oblique veins, the outer one shorter and strongly curved inward.       Abdomen. Marginal and spinal wax glands ( Figure 9). Cauda semicircular, length 0.35-0.57 × its BW, bearing three to four setae. Genital plate bearing 24-33 setae, mostly distributed on the apical margin. Spiracles inconspicuous. Siphunculi absent. Measurements presented in Table 3.

Etymology
The genus Qiao is named for QIAO Gexia, eminent Chinese aphidologist at the Institute of Zoology of the Chinese Academy of Sciences. The name is feminine in grammatical gender, thus the adjective jinshaensis is also feminine; the masculine and neuter forms are jinshaensis and jinshaense, respectively. The specific epithet is derived from the aphid's type locality in Yongshan County, along the Jinsha River, tributary of the Yangtze River. The aphid's host plant, Rhus wilsonii, is mainly distributed at a few narrow areas along the Jinsha River.

Biology
The galls are yellow-green or reddish in color and inflorescence-like in shape ( Figure 10). They possess multiple cavities and are positioned on the apical part of the stem. The gall measures approximately 110 by 90 mm and resembles the one formed by Nurudea shiraii (Matsumura, 1917

Biology
The galls are yellow-green or reddish in color and inflorescence-like in shape ( Figure  10). They possess multiple cavities and are positioned on the apical part of the stem. The gall measures approximately 110 by 90 mm and resembles the one formed by Nurudea shiraii (Matsumura, 1917). The autumn migrants of the aphid appear in late September. The tannin content of the gall was 52.3%, higher than the 35.2% of galls formed by N. shiraii [23].

Conclusions
Based on gall morphology alone, Qiao jinshaensis gen. et sp. nov. is most similar to species of Nurudea (see Figure 3 in Ren et al., 2018 [24]). However, it is quite distinct genetically and morphologically, suggesting the genus diverged early in the diversification of the Rhus-galling aphids. Despite this apparent divergence, these aphids, sometimes collectively considered the subtribe Melaphidina [5], are not especially speciose (there are now 17 species in 7 genera, including some species without a known host [25]). The genus Rhus dates to approximately 50 mya and is closely related to Pistacia [26], which is also known to harbor several genetically distinct but small Fordini genera. Price (2005) suggested that there may have been an early diversification among the Pistacia-galling aphids, now evident at the generic level, but with reduced recent speciation [27]. This hypothesis is also applicable to the Rhus-galling aphids. So far, most studies have focused on Rhusor Pistacia-feeding groups separately (e.g., [7,28]), but given the evolutionary proximity of both the aphids and their hosts, a phylogenetic evaluation of the entire tribe is needed.  Data Availability Statement: DNA sequence data are available at GenBank; specimen collection data are available from Hébert et al. [22]; specimens are available at the Institute of Zoology of the Chinese Academy of Sciences and the Ouellet-Robert Entomological Collection of the University of Montreal.