Landscape Heterogeneity Explains the Genetic Differentiation of a Forest Bird across the Sino-Himalayan Mountains.

Mountains are the world's most important centers of biodiversity. The Sino-Himalayan Mountains are global biodiversity hotspot due to their extremely high species richness and endemicity. Ample research investigated the impact of the Qinghai-Tibet Plateau uplift and Quaternary glaciations in driving species diversification in plants and animals across the Sino-Himalayan Mountains. However, little is known about the role of landscape heterogeneity and other environmental features in driving diversification in this region. We utilized whole genomes and phenotypic data in combination with landscape genetic approaches to investigate population structure, demography, and genetic diversity in a forest songbird species native to the Sino-Himalayan Mountains, the red-billed leiothrix (Leiothrix lutea). We identified 5 phylogeographic clades, including 1 in the East of China, 1 in Yunnan, and 3 in Tibet, roughly consistent with differences in song and plumage coloration but incongruent with traditional subspecies boundaries. Isolation-by-resistance model best explained population differentiation within L. lutea, with extensive secondary contact after allopatric isolation leading to admixture among clades. Ecological niche modeling indicated relative stability in the extent of suitable distribution areas of the species across Quaternary glacial cycles. Our results underscore the importance of mountains in the diversification of this species, given that most of the distinct genetic clades are concentrated in a relatively small area in the Sino-Himalayan Mountain region, while a single shallow clade populates vast lower-lying areas to the east. This study highlights the crucial role of landscape heterogeneity in promoting differentiation and provides a deep genomic perspective on the mechanisms through which diversity hotspots form.

Metabolic and microbial changes in light-vented bulbul during recent northward range expansion.

Endotherms recently expanding to cold environments generally exhibit strong physiological acclimation to sustain high body temperature. During this process, gut microbes likely play a considerable role in host physiological functions, including digestion and thermogenesis. The light-vented bulbul Pycnonotus sinensis represents one such species. It used to be restricted to the Oriental realm but expanded its distribution range north to the Palearctic areas during the past few decades. Here, we explored the seasonal dynamics of the resting metabolic rate (RMR) and microbiota for local and newly colonized populations of the species. Our results showed that the mass-adjusted RMR and body mass were positively correlated with latitude variations in both seasons. Consistently, the gut microbiota showed a corresponding variation to the northern cold environments. In the two northern populations, the alpha diversity decreased compared with those of the two southern populations. Significant differences were detected in dominant phyla, such as Firmicutes, Bacteroidetes, Proteobacteria, and Desulfobacterota in both seasons. The core microbiota showed geographic differences in the winter, including the elevated relative abundance of 5 species in northern populations. Finally, to explore the link between microbial communities and host metabolic thermogenesis, we conducted a correlation analysis between microbiota and mass-adjusted RMR. We found that more genera were significantly correlated with mass-adjusted RMR in the wintering season compared to the breeding season (71 vs. 23). These results suggest that microbiota of the lighted-vented bulbul linked with thermogenesis in diversity and abundance under northward expansion.

ATF4 Contributes to Abdominal Aortic Aneurysm Formation via Modulating M1 Macrophage Polarization and Inflammation.

Abdominal aortic aneurysm (AAA) is a potentially life-threatening vascular disease primarily in the male elderly population, but there is a lack of approved medical therapies to prevent the progression and rupture of AAA. Activating Transcription Factor 4 (ATF4) has been established to be involved in cardiovascular diseases, such as heart failure and calcific aortic valve disease. However, the role of ATF4 in the pathogenesis of AAA remains unclear. We found that ATF4 expression was significantly increased in patients with AAA and mouse models of AAA and was mainly confined to macrophages in arteries. ATF4 knockdown significantly attenuated aneurysm formation in experimental mouse model of AAA, while ATF4 overexpression promoted the development of AAA. RNA sequencing suggested that ATF4 was strongly related to the biological function of acute inflammatory response. Macrophages-specific ATF4 knockout significantly reduced the incidence and development of AAA, and decreased M1 polarization of macrophages in mice. Sphingomyelin phosphodiesterase 3 (SMPD3), a regulator of inflammatory responses in monocytes/macrophages, has been identified as a target gene of ATF4 through RNA sequencing, ChIP sequencing, and standard ChIP analyses. ATF4 induces M1 polarization of macrophages through the activation of SMPD3, thereby promoting inflammatory responses. Together, these results suggest that ATF4 mediated macrophage M1 polarization by regulating the expression of target genes SMPD3, leading to an increased inflammatory response, which further promotes the formation and development of AAA. These findings suggest ATF4 may be a new therapeutic target for AAA.