Libiao Zhang’s research while affiliated with Guangdong Academy of Agricultural Sciences and other places

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Publications (65)


Retraction Note: Origin and cross-species transmission of bat coronaviruses in China
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December 2024

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177 Reads

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Ben Hu

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Peter Daszak
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Comparative analysis of chromosome-level genomes provides insights into chromosomal evolution in Chiroptera

October 2024

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28 Reads

Integrative Zoology

Chiroptera (bats) presents a fascinating model due to its remarkable variation in chromosome numbers, which range from 14 to 62. This astonishing diversity makes bats an excellent subject for studying chromosome evolution. The black‐bearded tomb bat ( Taphozous melanopogon ) occupies a pivotal phylogenetic position within Chiroptera, emphasizing its crucial role in the systematic examination of bat chromosome evolution. In this study, we present the first chromosome‐level genome of T. melanopogon within the family Emballonuridae. Together with previously published genomes, we construct a strongly supported phylogenetic tree of bats, which supports that Emballonuridae forms a basal group within Yangochiroptera. Furthermore, we reconstruct ancestral karyotypes at key nodes along the bat phylogeny and conduct a synteny analysis among the genomes of 12 bat species. Our findings identified evolutionary breakpoint regions (EBRs) that are of particular interest. Notably, some bat genomes exhibit an enrichment of genes related to host defense against microbial pathogens within EBRs. Remarkably, one species possesses multiple copies of some β‐defensin genes, while six other species have experienced the loss of some β‐defensin genes due to EBRs. Furthermore, some olfactory receptor genes are located in EBRs of 12 species, 4 of which have a significant enrichment in sensory perception of smell. Together, our comparative genomic analysis underscores the potential link between chromosome rearrangements and the adaptation of bats to defend against microbial pathogens.


Construction of bat reference genomes and ACx atlases
(a) List of bat species included in the study with details relating to echolocation call type and acoustic energy. (b) Spectrograms of four bat species, among which, R. leschenaultia is referred from a previous study (see Methods for details). (c) Strategies for genome assembly with bat muscle tissue. (d) Hi-C maps for the genomes of two bat species prior to (left) and post manual curation (right). The dotted circle shows the position needed to be corrected. (e) QV base call accuracy values of the final assemblies. (f) Overview of genome annotation with 13 bat tissues. (g) Gene number and transcript number detected in each library. (h) UMAP visualization of ACx cells in each bat species. Cell types are indicated by colors. Exc, excitatory neuron; Inh, inhibitory neuron; Olig, oligodendrocyte; OPC, oligodendrocyte precursor cell; Astro, astrocyte; Endo, endothelial cell; Micro, microglia; Epend, ependymal cell. (i) Heatmap of top 10 marker genes (y axis) for each cell type (x axis) in 4 bat species. The color key from purple to yellow indicates low to high expression levels, respectively. (j) Cell type proportion in each sample. (k) Statistical analysis of the proportion of different cell types in left and right ACx. n = 7 for left ACx and n = 8 for right ACx. Data are mean values ± SD.
Source data
The differences in neuronal populations between microbats and megabats
(a) UMAP visualization of excitatory neuron subclusters in each bat species. Cell types are indicated by colors. (b) Dot plot showing expression pattern of representative marker genes in each excitatory neuron subcluster. Dot size and color represent the percentage of marker gene expression (Perc. Expr.) and average expression level (Aver. Expr.), respectively. (c) Heatmap of top 10 marker genes (y axis) for excitatory subclusters (x axis) in 4 bat species. (d) Heatmap of top 10 marker genes (y axis) for inhibitory subclusters (x axis) in 4 bat species. (e) UMAP visualization of inhibitory neuron subclusters split by species. (f) PCA visualization of PS⁺ inhibitory neurons in different bat species. (g) UMAP visualization of inhibitory neuron subclusters in four bat species by using different integration resolutions.
Construction of bat SCx atlas
(a) Gene number and transcript number detected in each library. (b) UMAP visualization of all SCx cells in two bats (left) and in each species (right). Cell types are indicated by colors. Exc, excitatory neuron; Inh, inhibitory neuron; Olig, oligodendrocyte; OPC, oligodendrocyte precursor cell; Astro, astrocyte; Endo, endothelial cell; Micro, microglia; Fibro, Fibroblast. (c) Dot plot showing the expression patterns of representative marker genes for each cell type of bat SCx. Dot size and color represent the percentage of marker gene expression (Perc. Expr.) and average expression level (Aver. Expr.), respectively. (d) Heatmap of top 10 marker genes (y axis) for SCx each cell type (x axis) in each bat species. The color key from purple to yellow indicates low to high expression levels, respectively. (e) UMAP visualization of inhibitory neuron subclusters in two bats. (f) Dot plot showing the expression patterns of representative marker genes for each subcluster of inhibitory neurons in bat SCx. Dot size and color represent the percentage of marker gene expression (Perc. Expr.) and average expression level (Aver. Expr.), respectively.
Validation of PV⁺ inhibitory neurons on ultrasound perception in mouse ACx
(a) Dot plot showing the expression patterns of PVALB, VIPR2, PDE3A and SYT2 in bat inhibitory neurons. Dot size and color represent the percentage of marker gene expression (Perc. Expr.) and average expression level (Aver. Expr.), respectively. (b) UMAP visualization (left) of all cell types of mouse ACx based on a previous study and violin plots of Syt2 and Pde3a expression patterns in all cell types (right). Gluta: glutamatergic neuron; Astro, astrocyte; Endo, endothelial cell; Micro-PVM: microglia-perivascular macrophage; Olig, oligodendrocyte; SMC-Peri: smooth muscle cell-pericyte; VLMC: vascular/leptomeningeal cell. (c) Gene ontology (GO) categories enriched in PS⁺ (top) or PP⁺ (bottom) neuron-specific DEGs. One-sided hypergeometric test ‘p-value’ was used and then adjusted for multiple comparisons. (d) Predicted cross-species cluster similarities of PS⁺ and PP⁺ inhibitory neurons between bat and mouse. (e) Heatmap of DEGs in PS⁺ and PP⁺ inhibitory neurons in bat and mouse. (f) Heatmaps of GCaMP signals in representative individual mice when exposed to 16 kHz or 63 kHz cue. Heatmaps are sorted by the ΔF/F (%). Color scale indicates ΔF/F (%).
DEGs of PS⁺ inhibitory neurons between microbats and megabats
(a) Venn diagram showing downregulated gene numbers in PS⁺ inhibitory neurons of microbats compared with those of megabats. (b) Heatmap of 369 downregulated genes in PS⁺ inhibitory neurons of microbats. (c) KEGG enrichment analysis using 369 downregulated genes in PS⁺ inhibitory neurons of microbats. One-sided hypergeometric test ‘p-value’ was used and then adjusted for multiple comparisons. (d) Synaptic vesicle cycle, the most enriched KEGG term of all 320 upregulated genes. (e) Spatial distribution of the expression patterns of synaptic vesicle cycle related genes in the ACx of M. ricketti and C. sphinx.

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Complexin-1 enhances ultrasound neurotransmission in the mammalian auditory pathway

June 2024

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170 Reads

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1 Citation

Nature Genetics

Unlike megabats, which rely on well-developed vision, microbats use ultrasonic echolocation to navigate and locate prey. To study ultrasound perception, here we compared the auditory cortices of microbats and megabats by constructing reference genomes and single-nucleus atlases for four species. We found that parvalbumin (PV)⁺ neurons exhibited evident cross-species differences and could respond to ultrasound signals, whereas their silencing severely affected ultrasound perception in the mouse auditory cortex. Moreover, megabat PV⁺ neurons expressed low levels of complexins (CPLX1–CPLX4), which can facilitate neurotransmitter release, while microbat PV⁺ neurons highly expressed CPLX1, which improves neurotransmission efficiency. Further perturbation of Cplx1 in PV⁺ neurons impaired ultrasound perception in the mouse auditory cortex. In addition, CPLX1 functioned in other parts of the auditory pathway in microbats but not megabats and exhibited convergent evolution between echolocating microbats and whales. Altogether, we conclude that CPLX1 expression throughout the entire auditory pathway can enhance mammalian ultrasound neurotransmission.



Fig. 1. Maps showing bat surveillance locations in Yunnan and Guangdong. The solid dots represent the nine locations where bat anal swabs were collected.
Fig. 2. Phylogenetic tree of the partial RNA-dependent RNA polymerase (RdRp) gene (387 bp) of coronavirus (CoV) strains found in bats. All CoVs detected are divided into seven clades, five of which belong to αCoV genus: HKU6r-CoV (light blue), Decacovirus (yellow), Nyctacovirus (purple), Minunacovirus (orange) and Rhinacovirus (green) clade, and two clades in βCoV genus: Merbecovirus (dark blue) and Sarbecovirus (red) clade. The scale bars represent 0.2 substitutions per nucleotide position.
Fig. 3. Genomic phylogenetic analysis of bat coronaviruses TyRo-CoV-162275 and TyRo-CoV-162269. A Genome structure of TyRo-CoV-162275. B Phylogenetic tree based on the nucleotide sequences of the complete genomes of representative αCoV and βCoV. Merbecoviruses are shown in red, and Nyctacoviruses are shown in yellow. Shaded colours represent different subgenera of coronaviruses. The scale bars represent 0.05 substitutions per nucleotide position. C Similarity plot based on the full-length genome sequences. TyRo-CoV-162275 was used as a query sequence, Tylonycteris bat CoV HKU4-1, Pipistrellus bat CoV HKU5-1, pangolin CoV MjHKU4r-CoV-1-4, P251T, and human MERS-CoV were used as reference sequences. D Full spike amino acid and nucleotide similarity between P251T, MjHKU4r-CoV-1-4, MERS-CoV, HKU4-CoV, HKU5-CoV, and TyRo-CoV-162275.
Pangolin HKU4-related coronaviruses found in greater bamboo bat from southern China

November 2023

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88 Reads

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2 Citations

Virologica Sinica

Coronavirus (CoV) spillover originating from game animals, particularly pangolins, is currently a significant concern. Meanwhile, vigilance is urgently needed for coronaviruses carried by bats, which are known as natural reservoirs of many coronaviruses. In this study, we collected 729 anal swabs of 20 different bat species from nine locations in Yunnan and Guangdong provinces, southern China, in 2016 and 2017, and described the molecular characteristics and genetic diversity of alphacoronaviruses (αCoVs) and betacoronaviruses (βCoVs) found in these bats. Using RT-PCR, we identified 58 (8.0%) bat CoVs in nine bat species from six locations. Furthermore, using the Illumina platform, we obtained two representative full-length genomes of the bat CoVs, namely TyRo-CoV-162275 and TyRo-CoV-162269. Sequence analysis showed that TyRo-CoV-162275 shared the highest identity with Malayan pangolin (Manis javanica) HKU4-related coronaviruses (MjHKU4r-CoVs) from Guangxi Province, whereas TyRo-CoV-162269 was closely related to HKU33-CoV discovered in a greater bamboo bat (Tylonycteris robustula) from Guizhou Province. Notably, TyRo-CoV-162275 has a putative furin protease cleavage site in its S protein and is likely to utilize human dipeptidyl peptidase-4 (hDPP4) as a cell-entry receptor, similar to MERS-CoV. To the best of our knowledge, this is the first report of a bat HKU4r-CoV strain containing a furin protease cleavage site. These findings expand our understanding of coronavirus geographic and host distributions.


Cross-species comparison illuminates the importance of iron homeostasis for splenic anti-immunosenescence

September 2023

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29 Reads

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4 Citations

Although immunosenescence may result in increased morbidity and mortality, many mammals have evolved effective immune coping strategies to extend their lifespans. Thus, the immune systems of long-lived mammals present unique models to study healthy longevity. To identify the molecular clues of anti-immunosenescence, we first built high-quality reference genome for a long-lived myotis bat, and then compared three long-lived mammals (i.e., bat, naked mole rat, and human) versus the short-lived mammal, mouse, in splenic immune cells at single-cell resolution. A close relationship between B:T cell ratio and immunosenescence was detected, as B:T cell ratio was much higher in mouse than long-lived mammals and significantly increased during aging. Importantly, we identified several iron-related genes that could resist immunosenescence changes, especially the iron chaperon, PCBP1, which was upregulated in long-lived mammals but dramatically downregulated during aging in all splenic immune cell types. Supportively, immune cells of mouse spleens contained more free iron than those of bat spleens, suggesting higher level of ROS-induced damage in mouse. PCBP1 downregulation during aging was also detected in hepatic but not pulmonary immune cells, which is consistent with the crucial roles of spleen and liver in organismal iron recycling. Furthermore, PCBP1 perturbation in immune cell lines would result in cellular iron dyshomeostasis and senescence. Finally, we identified two transcription factors that could regulate PCBP1 during aging. Together, our findings highlight the importance of iron homeostasis in splenic anti-immunosenescence, and provide unique insight for improving human healthspan.


Sequencing data. (A) Length distribution of raw data. (B) Number distribution of contigs and genes. (C) Length distribution of N50 contigs and genes.
Diversity of gut microbiota in various species of bats. (A) Top 18 microbial phyla in gut microbiota of bats. The bar below the phylogenetic tree indicates divergence time of the bat species. (B) Diversity of gut microbiota in bats with different diet habits (the two upper panels) and those of different phylogenies (at genus level, the two lower panels).
Major microbial species in gut microbiota of bats. (A) Gray lines show results of 5 repeats of RF modeling with 10-fold cross validations. Dark lines indicate average values of the 5 repeats. Dashed lines denote the lowest point of the dark line, where the model had the lowest out-of-bag (OOB) error. The bar length in MeanDecreaseGini shows the extent of microbes affecting node impurity in RF modeling, and a microbe with a longer bar has a higher effect on the composition of gut microbiota. (B) Phylogenetic tree of the 91 most significant microbes among bats. Red branches represent the 53 most significant microbes among bats of different phylogenies, and green branches denote the 38 most significant microbes among bats with different dietary habits. Scale bar length indicates the number of amino acid substitutions per site.
Significantly changed bacterial species and metabolic pathways between IB and IFB. (A) The 62 significantly changed bacterial species between IB and IFB. The phylogenetic relationships of these species are shown in the right panel. (B) Significantly altered KEGG pathways between IB and IFB.
The difference in the composition of gut microbiota is greater among bats of different phylogenies than among those with different dietary habits

July 2023

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67 Reads

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1 Citation

Bats have a very long evolutionary history and are highly differentiated in their physiological functions. Results of recent studies suggest effects of some host factors (e.g., phylogeny and dietary habit) on their gut microbiota. In this study, we examined the gut microbial compositions of 18 different species of bats. Results showed that Firmicutes, Gammaproteobacteria, and Actinobacteria were dominant in all fecal samples of bats. However, the difference in the diversity of gut microbiota among bats of different phylogenies was notable (p = 0.06). Various species of Firmicutes, Actinobacteria, and Gammaproteobacteria were found to contribute to the majority of variations in gut microbiota of all bats examined, and Aeromonas species were much more abundant in bats that feed on both insects and fish than in those of insectivores. The abundance of various species of Clostridium, Euryarchaeota, and ancient bacterial phyla was found to vary among bats of different phylogenies, and various species of Vibrio varied significantly among bats with different dietary habits. No significant difference in the number of genes involved in various metabolic pathways was detected among bats of different phylogenies, but the abundance of genes involved in 5 metabolic pathways, including transcription; replication, recombination, and repair; amino acid transport and metabolism; and signal transduction mechanisms, was different among bats with different dietary habits. The abundance of genes in 3 metabolic pathways, including those involved in stilbenoid, diarylheptanoid, and gingerol biosynthesis, was found to be different between insectivorous bats and bats that feed on both insects and fish. Results of this study suggest a weak association between dietary habit and gut microbiota in most bats but a notable difference in gut microbiota among bats of different phylogenies.


Confirmation of the existence of Himalayan long-eared bats, Plecotus homochrous (Chiroptera, Vespertilionidae), in China

May 2023

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208 Reads

The existence of Himalayan long-eared bats, Plecotus homochrous (Chiroptera, Vespertilionidae), in China has not been previously confirmed. In this study, four bats captured with harp traps from two sites in the Maoershan National Nature Reserve in Guangxi, China were investigated. These bats have long, wide auricles, each with a prominent tragus. The length of each auricle is about the same as that of a forearm. Hairs on the ventral fur have a dark base with mixed grey and yellowish tips; those on the dorsal fur also have a dark base and are bicolored with brown tips. The thumbs are very short. A concavity is present in the front of the dorsal side of the cranium. Based on morphological characteristics and phylogeny using Cyt b gene sequences, these bats were identified as P. homochrous , thus confirming the existence of Himalayan long-eared bats in China.


Fig. 2. Phylogenetic tree and genome synteny. (A) A maximum likelihood phylogenetic tree of 18 mammals. The newly assembled C. sphinx genome is indicated by a red star, and all seven bat species with chromosome-level genomes are underlined. Numbers on the ancestral branch leading to Pteropodidae denote expanded (purple) and contracted (red) gene families. Branch lengths are scaled by millions of years. The dot plots of syntenic sequences of chromosome X are shown on the top; the X sequences from seven non-bat mammals and six chromosome-level bats are aligned to X sequence of C. sphinx, and high-stringency alignments are shown by black dots. (B) Circos plots showing genome synteny. The chromosome-level genomes of six bats and horse were aligned to C. sphinx genome. Syntenic blocks are linked between genomes in Circos plots. Chromosome order of C. sphinx is indicated in the rightmost Circos plot, and LG10 is the X chromosome of C. sphinx.
Fig. 3. Evolution of gene families. (A) Increasing trend of all gene families and decreasing trend of core gene families as number of pteropodid genomes increases. (B) Loss of the key inflammasome NLRP1 gene in Pteropodidae. The orthologous relationships of NLRP1 and its surrounding genes were shown. Species names in the left side indicate pteropodids (in yellow), other bats (in blue), and non-bat mammals (in black). Colored bars represent five genes surrounding NLRP1 that have syntenic relationships, and unique genes in a species are indicated by gray bars. The black arrows above the gene name indicate the direction of a gene from 5′ to 3′. (C) Duplication of C5AR2 in pteropodids. Left: Two copies of C5AR2 are shown in two pteropodids, with the thick orange lines indicating SDs; the black arrows indicate the direction of a gene from 5′ to 3′. Right: C. sphinx with two C5AR2 copies was compared to each of non-pteropodid bats with one C5AR2 copy, with the horse as an example of nonbat mammals.
Fig. 4. Pteropodid-specific molecular adaptations of immune genes. (A) Schematic diagram showing pteropodid-specific PSGs (in orange), REGs (in green), gene duplication (in red), and gene loss (in blue). The thick red arrows indicate dampened expression. dsRNA, double-stranded RNA; NF-κB, nuclear factor κB. (B) Histogram plot showing the highest ω (means ± SE) in pteropodids as compared to other bats or mammals. Statistical significances were determined by Student's t test. (C) Histogram plot showing more genes undergoing positive selection in pteropodids than other bats or non-bat mammals. Statistical significances were determined by Fisher's exact test. Tian et al., Sci. Adv. 9, eadd0141 (2023) 5 May 2023 6 of 16
Fig. 5. Evidence of pteropodid-specific changes in MyD88 for reducing its binding affinity with TLR2. (A) Alignment of MyD88 protein sequences from pteropodids, other bats, and non-bat mammals. Dots indicate identical amino acids to the final sequence (human), and dashes denote alignment gaps. Four interfacing residues between the TLR2-MyD88 complexes are shaded in red. (B) Comparison of MyD88 protein structural models between pteropodids (blue) and humans (green). Four mutated residues of MyD88 in pteropodids are shown in red, whereas those in humans are shown in black. Structural models of MyD88 proteins were predicted by I-TASSER v.5.1 (120). (C) Immunoprecipitates and total lysates from bat Paki cells cotransfected with two combinations of plasmids: P. alecto TLR2/MyD88-MUT and P. alecto TLR2/MyD88-WT. Pteropodid-specific changes in MyD88 were shown to reduce its binding affinity with TLR2. β-Tubulin is a housekeeping gene used as an internal control; HA denotes the hemagglutinin tag that is a 9-amino acid-long peptide corresponding to residues 98 to 106 of the human influenza HA molecule. Anti-HA, HAtag antibody; IgG, nonspecific immunoglobulin G antibody; input, total lysates for immunoblotting; IB, immunoblotting.
Fig. 6. Functional evidence of MyD88 for inhibiting excessive inflammatory activation in pteropodids. (A) Comparisons of relative expression levels of inflammatory cytokines between MyD88-MUT (MUT) variants and MyD88-WT (WT) in PaKi and PEAKrapid cells, respectively, when stimulated by the TLR2 agonist Pam 3 CSK 4 . Mutants contained the four mutations of human-specific residues (pMyD88-MUT) in PaKi cells and the four mutations of pteropodid-specific residues (hMyD88-MUT) in PEAKrapid cells. Expression levels in PaKi and PEAKrapid cells with the empty plasmid (mock) were used for normalization, respectively. The data of three independent experiments are expressed as the means ± SE by Student's t test (**0.001 ≤ P < 0.01; *0.01 ≤ P < 0.05; n.s., not significant). (B) Comparisons of relative expression levels of inflammatory cytokines between hMyD88-MUT variants and hMyD88-WT cells of PEAKrapid, when stimulated by the E protein of SARS-CoV-2. Expression levels in PEAKrapid cells with the empty plasmid (mock; as control) were used for normalization. Data for three independent experiments expressed as the means ± SE with significance estimated by the Student's t test (*0.01 ≤ P < 0.05). (C) Schematic diagram showing TLR2-MyD88 signaling pathway.
Comparative analyses of bat genomes identify distinct evolution of immunity in Old World fruit bats

May 2023

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235 Reads

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22 Citations

Science Advances

Bats have been identified as natural reservoir hosts of several zoonotic viruses, prompting suggestions that they have unique immunological adaptations. Among bats, Old World fruit bats (Pteropodidae) have been linked to multiple spillovers. To test for lineage-specific molecular adaptations in these bats, we developed a new assembly pipeline to generate a reference-quality genome of the fruit bat Cynopterus sphinx and used this in comparative analyses of 12 bat species, including six pteropodids. Our results reveal that immunity-related genes have higher evolutionary rates in pteropodids than in other bats. Several lineage-specific genetic changes were shared across pteropodids, including the loss of NLRP1, duplications of PGLYRP1 and C5AR2, and amino acid replacements in MyD88. We introduced MyD88 transgenes containing Pteropodidae-specific residues into bat and human cell lines and found evidence of dampened inflammatory responses. By uncovering distinct immune adaptations, our results could help explain why pteropodids are frequently identified as viral hosts.


Comparative transcriptome analysis reveals molecular adaptations underlying distinct immunity and inverted resting posture in bats

September 2022

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76 Reads

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5 Citations

Integrative Zoology

Understanding how natural selection shapes unique traits in mammals is a central topic in evolutionary biology. The mammalian order Chiroptera (bats) is attractive for biologists as well as the general public due to their specific traits of extraordinary immunity and inverted resting posture. However, genomic resources for bats that occupy key phylogenetic positions are not sufficient, which hinders comprehensive investigation of the molecular mechanisms underpinning the origin of specific traits in bats. Here, we sequenced the transcriptomes of five bats that are phylogenetically divergent and occupy key positions in the phylogenetic tree of bats. In combination with the available genomes of 19 bats and 21 other mammals, we built a database consisting of 10,918 one-to-one ortholog genes and reconstructed phylogenetic relationships of these mammals. We found that genes related to immunity, bone remodeling and cardiovascular system are targets of natural selection along the ancestral branch of bats. Further analyses revealed that the T cell receptor signaling pathway involved in immune adaptation is specifically enriched in bats. Moreover, molecular adaptations of bone remodeling, cardiovascular system, and balance sensing may help to explain the reverted resting posture in bats. Our study provides valuable transcriptome resources, enabling us to tentatively identify genetic changes associated with bat-specific traits. This work is among the first to advance our understanding of molecular underpinnings of inverted resting posture in bats, which could provide insight into healthcare applications such as hypertension in humans. This article is protected by copyright. All rights reserved.


Citations (52)


... In the nervous system of C. elegans and at the Drosophila neuromuscular junction, CPX primarily inhibits vesicle release [41][42][43][44]. In contrast, in the nervous systems of mammals and in the auditory neurotransmission of bats, CPX predominantly acts as a facilitator of vesicle release [45,46].These evolutionary differences likely result from several factors. First, structural adaptations of CPX across species, particularly in its interactions with the SNARE complex, may have driven functional divergence. ...

Reference:

Complexin regulation of synaptic vesicle release: mechanisms in the central nervous system and specialized retinal ribbon synapses
Complexin-1 enhances ultrasound neurotransmission in the mammalian auditory pathway

Nature Genetics

... The primer sequences were as follows: HAV-F1089: GAGATATAYACWTATGCIAGATTTGG, HAV-R1481: CTRAATTCRTTICT-CATCATYTGTG, and HAV-R1544: GACATYTTIGCYCTIGCATCYTC [7,17]. Each small mammal species was identified by analyzing the external morphological characteristics and mitochondrial cytochrome b (Cyt-b) gene sequences [18][19][20]. The primer sequences for Cyt-b amplification were: Cytb-F: ATGATATGAAAAACCATCGTTG and Cytb-R: TTTCC-NTTTCTGGTTTACAAGAC. ...

Pangolin HKU4-related coronaviruses found in greater bamboo bat from southern China

Virologica Sinica

... Hepatocyte-specific deletion of Pcbp1 results in iron dyshomeostasis, mitochondrial damage, and ferroptotic cell death (Protchenko et al., 2021). Recent research has shown that decreased Pcbp1 expression in splenic and liver immune cells leads to iron dyshomeostasis and senescence, findings that are in line with our results (He et al., 2023). These findings suggest that Pcbp1 may serve as a universal anti-immunosenescence gene across different organs. ...

Cross-species comparison illuminates the importance of iron homeostasis for splenic anti-immunosenescence

... A lower availability of food or a forced shift towards other food sources could disrupt the already precarious natural balance that many species, threatened or at risk of extinction, are a part of. Eventually, it would be useful to manage the ecotones resulting from urbanization and avoid the destruction of natural habitats, their trade, and deforestation [41,88,134,135], and to consider the crucial role of bats in various ecosystem services. This requires a One Health approach to fill knowledge gaps and ensure the management of mitigation strategies, not only to minimize the risk of zoonoses but also to ensure the conservation of these highly useful species [136][137][138][139]. ...

The difference in the composition of gut microbiota is greater among bats of different phylogenies than among those with different dietary habits

... In recent years, the increasing availability of genomic resources for bats has shed light on significant questions regarding genetic and molecular mechanisms at various levels (e.g., Ricci et al. 2023;Scheben et al. 2023;Schneor et al. 2023). Some of these comparisons have highlighted unique features of the bat immune system, particularly in species from the suborder Yinpterochiroptera (e.g., Chattopadhyay et al. 2020;Tian et al. 2023). There is an ongoing debate about discrepancies in antiviral expression among different bat species, with many showing limited induction of antiviral responses. ...

Comparative analyses of bat genomes identify distinct evolution of immunity in Old World fruit bats

Science Advances

... We found that in contrast to the to the majority of innate immune genes that do not significantly differ in steady-state expression between the species in either lung or gut cells, many complement system genes are uniquely expressed in bat epithelial cells from both tissues. Interestingly, recent evolutionary analyses comparing bat genes with orthologs in other mammals found evidence for lineage-specific adaptation in coding sequences of bat complement system genes [66][67][68] . In agreement with this, we found that a significant fraction of the complement system genes also show elevated evolutionary rates and signatures of positive selection in their coding sequences when compared across bat species. ...

Comparative transcriptome analysis reveals molecular adaptations underlying distinct immunity and inverted resting posture in bats

Integrative Zoology

... In the case of SARS-CoV, Chinese horseshoe bats from the Rhinolophus family in Yunnan, China, were identified as having close genetic resemblance [18] Some bat CoV. like RaTG13, show similar sequences up to 96% nt with SARS-CoV-2 [19]. ...

Epidemiology and Genomic Characterization of Two Novel SARS-Related Coronaviruses in Horseshoe Bats from Guangdong, China

... In mice, the removal of the olfactory bulb eliminates maternal aspects in females [129]. A study by Liang et al. [130] concluded that the mother Tylonycteris pachypus bats recognize their young by scent. Although pheromones and olfactory stimuli are important for altricial species, in rabbit pups it has been reported that they search for the nipple with or without the association of suckling with odors [131]. ...

The role of olfactory cues in mother–pup, groupmate, and sex recognition of lesser flat‐headed bats, Tylonycteris pachypus

... Considering that rodents are carriers of at least 60 zoonotic diseases, their proximity to humans may pose a substantial threat to human health [6,7]. Accordingly, alpha-and betacoronaviruses have been identified in these animal species in China and Europe [7][8][9][10]. Indeed, both HCoV-OC43 and HCoV-KU1 are human coronaviruses (CoVs) that have a rodent origin, underlining the potential role of these animals in disease transmission [11]. ...

A Novel Potentially Recombinant Rodent Coronavirus with a Polybasic Cleavage Site in the Spike Protein

... KX783428), NFWKT7F (KX783427), RATLC11A (KX783425), NCHN06IO (KX783431), and NCGX12IN (KX783432). Comprehending the coevolutionary relationship between rosaviruses and their hosts provides valuable insights into viral transmission between wild small mammals and humans and serves as a reference for monitoring efforts related to their spread [41]. Despite the absence of clear evidence for homologous recombination among rosaviruses in this study, P1 proteins, which have relatively high genetic variability, contain the most diverse motif responsible for encoding the viral capsid protein ( Figure 6). ...

Cospeciation of coronavirus and paramyxovirus with their bat hosts in the same geographical areas

BMC Ecology and Evolution