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Muntjac deer have experienced drastic karyotype changes during their speciation, making it an ideal model for studying mechanisms and functional consequences of mammalian chromosome evolution. Here we generated chromosome-level genomes for Hydropotes inermis (2n = 70), Muntiacus reevesi (2n = 46), female and male M. crinifrons (2n = 8/9) and a contig-level genome for M. gongshanensis (2n = 8/9). These high-quality genomes combined with Hi-C data allowed us to reveal the evolution of 3D chromatin architectures during mammalian chromosome evolution. We find that the chromosome fusion events of muntjac species did not alter the A/B compartment structure and topologically associated domains near the fusion sites, but new chromatin interactions were gradually established across the fusion sites. The recently borne neo-Y chromosome of M. crinifrons , which underwent male-specific inversions, has dramatically restructured chromatin compartments, recapitulating the early evolution of canonical mammalian Y chromosomes. We also reveal that a complex structure containing unique centromeric satellite, truncated telomeric and palindrome repeats might have mediated muntjacs’ recurrent chromosome fusions. These results provide insights into the recurrent chromosome tandem fusion in muntjacs, early evolution of mammalian sex chromosomes, and reveal how chromosome rearrangements can reshape the 3D chromatin regulatory conformations during species evolution. Muntjac deer underwent rapid species radiation and dramatic chromosome fusions within a short period of time. Here the authors reveal that repeat sequences likely mediated illegitimate recombination to result in chromosome fusions and that 3D chromatin architecture around fusion sites have no significant change, while significant interactions across fusion sites were gradually established after speciation.

Abstract This study aimed to identify the phylogenetic similarities among the muntjac (Muntiacus spp.). The phylogenetic similarities among seven major muntjac species were studied by comparing the nucleotide sequence of 16s rRNA and cytochrome b genome. Nucleotide sequences, retrieved from NCBI databases were aligned by using DNASTAR software. A phylogenetic tree was created for the selected species of muntjac by using the maximum likelihood method on MEGA7 software. The results of nucleotide sequences (16s rRNA) showed phylogenetic similarities between, the M. truongsonensis and M. rooseveltorum had the highest (99.2%) while the lowest similarities (96.8%) found between M. crinifrons and M. putaoensi. While the results of nucleotide sequences (Cty b) showed the highest similarity (100%) between M. muntjak and M. truongsonensis and the lowest s (91.5%) among M. putaoensis and M. crinifrons. The phylogenetic tree of muntjac species (16s rRNA gene) shows the main two clusters, the one including M. putaoensis, M. truongsonensis, M. rooseveltorum, and M. muntjak, and the second one including M. crinifrons and M. vuquangensis. The M. reevesi exists separately in the phylogenetic tree. The phylogenetic tree of muntjac species using cytochrome b genes shows that the M. muntjak and M. truongsonensis are clustered in the same group. Resumo Este estudo visou identificar as semelhanças filogenéticas entre os muntjac (Muntiacus spp.). As semelhanças filogenéticas entre sete grandes espécies muntjac foram estudadas comparando a sequência de nucleótidos de 16s rRNA e genoma citocromo b. As sequências de nucleótidos, obtidas a partir de bases de dados NCBI, foram alinhadas utilizando o software DNASTAR. Foi criada uma árvore filogenética para as espécies selecionadas de muntjac utilizando o método de probabilidade máxima no software MEGA7. Os resultados das sequências de nucleótidos (16s rRNA) mostraram semelhanças filogenéticas entre o M. truongsonensis e o M. rooseveltorum tiveram o maior número (99,2%) enquanto as semelhanças mais baixas (96,8%) encontradas entre M. crinifrons e M. putaoensi. Enquanto os resultados das sequências de nucleótidos (Cty-b) apresentaram a maior semelhança (100%) entre M. muntjak e M. truongsonensis e os mais baixos (91,5%) entre M. putaoensis e M. crinifrons. A árvore filogenética das espécies muntjac (gene rRNA 16s) mostra os dois principais aglomerados, o que inclui M. putaoensis, M. truongsonensis, M. rooseveltorum e M. muntjak, e o segundo incluindo M. crinifrons e M. vuquangensis. O M. reevesi existe separadamente na árvore filogenética. A árvore filogenética das espécies muntjac usando genes citocromo b mostra que os M. muntjak e M. truongsonensis estão agrupados no mesmo grupo.

The family Cervidae is the second most diverse in the infraorder Pecora and is characterized by variability in the diploid chromosome numbers among species. X chromosomes in Cervidae evolved through complex chromosomal rearrangements of conserved segments within the chromosome, changes in centromere position, heterochromatic variation, and X-autosomal translocations. The family Cervidae consists of two subfamilies: Cervinae and Capreolinae. Here we build a detailed X chromosome map with 29 cattle bacterial artificial chromosomes of representatives of both subfamilies: reindeer ( Rangifer tarandus ), gray brocket deer ( Mazama gouazoubira ), Chinese water deer ( Hydropotes inermis ) (Capreolinae); black muntjac ( Muntiacus crinifron s), tufted deer ( Elaphodus cephalophus ), sika deer ( Cervus nippon ) and red deer ( Cervus elaphus ) (Cervinae). To track chromosomal rearrangements during Cervidae evolution, we summarized new data, and compared them with available X chromosomal maps and chromosome level assemblies of other species. We demonstrate the types of rearrangements that may have underlined the variability of Cervidae X chromosomes. We detected two types of cervine X chromosome—acrocentric and submetacentric. The acrocentric type is found in three independent deer lineages (subfamily Cervinae and in two Capreolinae tribes—Odocoileini and Capreolini). We show that chromosomal rearrangements on the X-chromosome in Cervidae occur at a higher frequency than in the entire Ruminantia lineage: the rate of rearrangements is 2 per 10 million years.

The competitive relationship and coexistence pattern among close related species have long been one of the hot issues in ecological research. Interspecies interactions can exert important influences on the local distribution of rare species. Black muntjac Muntiacus crinifrons is an endemic species to eastern China, currently restricted to limited regions. In contrast, Chinese muntjac Muntiacus reevesi is the most common and widespread deer in southern China. Both species co‐occur in southern Anhui and western Zhejiang Province. Little is known about the interaction of these two sympatric‐related species. In this study, to investigate the site use determinants and co‐occurrence pattern of the two sympatric muntjac species, we conducted a camera trap survey across about 250 km2 in mountainous area of southern Anhui Province, China. We adopted a multistep approach to incorporate habitat preferences while modeling occupancy and detection. We found that the two species did not separate along elevation gradient (range from 400 m to 1,400 m) as described in previous studies. Results of single‐species occupancy models indicated that elevation had positive effects on the site use of both species, while slope had an opposite influence on their site use. Positive effects of elevation on the site use implied that both species try to avoid human interference at low elevations. Significant negative effect of slope on the site use of black muntjac suggested that the species prefer habitat with gentle slope and avoided steep. Co‐occurrence models and species interaction factors provided evidence that the two muntjac species had an independent occupancy (ψBM CM = ψBM cm, SIF = 1) and exhibited a positive species interaction in detection probability (pBM < rBM CM). Combined with the results of previous studies, we suggested that it was fine differentiation in microhabitats and food resources utilization rather spatial or temporal segregation that allowed the two species co‐occurrence. The site use determinants revealed in our study would be useful for the habitat conservation and restoration for the rare black muntjac, and the co‐occurrence pattern of the two sympatric muntjac species could provide useful information for deep understanding of the coexistence mechanism among forest‐dwelling ungulates. Our study found that two sympatric‐related muntjac species, black muntjac and Chinese muntjac, did not separate along elevation gradient as described in previous studies. Co‐occurrence models and species interaction factors suggested that the two muntjacs have an independent occupancy. We suggested that it was fine differentiation in microhabitats and food resources utilization rather spatial or temporal segregation that allowed the two species co‐occurrence.

The leaf muntjac (Muntiacus putaoensis) is an endemic deer species found in the east trans-Himalayan region. In recent years, population numbers have decreased due to heavy hunting and habitat loss, and little genetic data exists for this species, thus our knowledge of distribution rangs and population sizes likewise remain limited. We obtained mtDNA genes and the complete mitochondrial genome sequence of M. putaoensis using PCR, followed by direct sequencing. The complete mitogenome sequence was determined as a circular 16 349 bp mitochondrial genome, containing 13 protein-coding genes, two rRNA genes, 22 tRNA genes, and one control region, the gene composition and order of which were similar to most other vertebrates so far reported. Most mitochondrial genes, except for ND6 and eight tRNAs, were encoded on the heavy strand. The overall base composition of the heavy strand was 33.1% A, 29.3% T, 24.2% C, and 13.4% G, with a strong AT bias of 62.4%. There were seven regions of gene overlap totaling 95 bp and 11 intergenic spacer regions totaling 74 bp. Phylogenetic analyses (ML and BI) among the Muntiacus genus based on the sequenced of mitogenome and ND4L-ND4 supported M. putaoensis as a member of Muntiacus, most closely related to M. vuquangensis. However, when analyses based on cyt b included two more muntjacs, M. truongsonensis was most closely related to M. putaoensis rather than M. vuquangensis, and together with M. rooseveltorum, likely forming a M. rooseveltorum complex of the species. This study will help in the exploration of the evolutionary history and taxonomic status of the leaf muntjac, as well as its protection as a genetic resource.

正强化训练被广泛应用于圈养动物的饲养管理中，对黑麂（Muntiacus crinifrons）这类神经敏感物种尤其重要。通过对北京、杭州和合肥三地动物园的34只黑麂进行正强化行为训练，观察并记录训练前后的行为，探讨正强化训练对圈养黑麂行为模式的影响。结果显示：训练后黑麂的运动行为显著提高，静止行为，尤其是站息行为显著减少，表明正强化训练有效增加了黑麂的运动时长和频次，对其健康具有积极作用。此外，训练还降低了黑麂的警戒行为，有助于脱敏，并可应用于治疗和运输等饲养管理，减少应激行为。黑麂的摄食行为则存在显著的地域性差异，北京和合肥地区的黑麂经过训练后摄食行为增加的程度大于杭州，可能与黑麂对训练人员熟悉程度有关。因此，正强化行为训练可在短时间内提高圈养黑麂自然行为的表达，减少应激反应，优化饲养管理模式。

In order to accurately and comprehensively understand the daily activity rhythm of black muntjac (Muntiacus crinifrons) in Jiulongshan National Nature Reserve, seasonal variations in daily activity rhythm and vertical migration of black muntjac were studied using the infrared camera trapping approach from October 2017 to February 2021. A total of 352 photos and 243 effective detection of black muntjac were collected. The results showed that black muntjac was a diurnal animal with double peaks in the morning and dusk. Comparison of the four seasons revealed that activity intensity in summer was higher than that in spring, autumn and winter, and there were differences in time periods and quantity of the daily activity peaks among different seasons. The preferred habitat of black muntjac was located in areas with slope in between 20 and 40 degrees, and its varied in altitude and slope position among seasons.

为准确全面地了解黑麂（Muntiacus crinifrons）在九龙山国家级自然保护区的日活动节律和某些栖息地生态因子选择的季节性规律，于2017年10月—2021年2月，在九龙山国家级自然保护区采用红外相机法对黑麂日活动节律和垂直迁移的季节变化进行研究。研究期间，共拍摄到352张黑麂照片，提取到243次有效探测。结果显示：黑麂是晨昏双峰型的昼行性动物。通过四季对比发现，黑麂夏季的活动强度比春季、秋季和冬季高，而各季节间的日活动高峰期时间段和数量存在差异。黑麂 偏好栖息于坡度为20°~40°的栖息地，海拔选择和坡位选择存在季节性垂直迁移现象。

Full cytochrome b gene sequence of mtDNA was used to identify and analyze four skin samples collected from Tibet, China in this research. By searching for highly similar sequences (megablast) on NCBI, we found all four samples have the highest similarities with the published sequence: AY239042 of the black muntjac (Muntiacus crinifrons). By comparing our sequences to those available on GenBank, all four samples were identified as the black muntjac (Muntiacus crinifrons) by high sequence similarity. We therefore record two new localities for the black muntjac and it is a new distribution in Tibet and hope this study will not only promote more advanced researches on the evolution and phylogeny about this species, but also enhance the conservation work for this species and local biodiversity.

The black muntjac (Muntiacus crinifrons) is a rare deer found only in a restricted region in east China. Recent studies of mitochondrial DNA diversity have shown a markedly low level of nucleotide diversity for the species, and the Suichang population was genetically differentiated from the two other populations, in Huangshan and Tianmushan mountains. In this study, we extended the analysis of genetic diversity and population subdivision for the black muntjac using data from 11 highly polymorphic nuclear DNA microsatellite loci. Contrary to the results based on mtDNA data, the microsatellite loci revealed that the black muntjac retained a rather high nuclear genetic diversity (overall average H E = 0.78). Nevertheless, both types of markers supported the idea that the extant black muntjac population is genetically disrupted (overall [Greek Phi symbol] ST = 0.16 for mtDNA and overall F ST = 0.053 for microsatellite, both P < 0.001). The correlation between genetic differentiation and geographic distance was not significant (Mantel test; P > 0.05), implying that the patterns of genetic differentiation observed in this study might result from recent habitat fragmentation or loss. Based on the results from the mtDNA and nuclear DNA data sets, two management units were defined for the species, Huangshan/Tianmushan and Suichang. We also recommend that a new captive population be established with individuals from the Suichang region as a founder source.