严重发热伴血小板减少综合征病毒感染 IFNAR1-/- 小鼠时,A1 反应性星形胶质细胞和 IFNAR 信号共同诱导神经细胞死亡。

IF 6.8 3区 医学 Q1 VIROLOGY
Morgan Brisse, Hinh Ly
{"title":"严重发热伴血小板减少综合征病毒感染 IFNAR1-/- 小鼠时,A1 反应性星形胶质细胞和 IFNAR 信号共同诱导神经细胞死亡。","authors":"Morgan Brisse,&nbsp;Hinh Ly","doi":"10.1002/jmv.29949","DOIUrl":null,"url":null,"abstract":"<p>Severe fever with thrombocytopenia syndrome (SFTS) is caused by the SFTS virus (SFTSV), a bunyavirus that is endemic throughout eastern Asia. SFTSV was first discovered in 2009 in central China<span><sup>1</sup></span> and has since infected about 5500 people in China<span><sup>2</sup></span> and approximately 800 each in Japan and South Korea.<span><sup>3</sup></span> The disease (SFTS) is characterized by fever, thrombocytopenia, and central nervous system (CNS) symptoms including headache, vertigo, coma, and encephalitis<span><sup>4, 5</sup></span> which has impacted as many as 45% of SFTS patients.<span><sup>6</sup></span> The mortality rate caused by SFTSV infection varies by region and by year with reported rates as high as 27%.<span><sup>7, 8</sup></span> There are currently no therapeutics or vaccines available for SFTS treatment and prevention.</p><p>While clinical manifestations such as decreased blood flow to the brain resulting from systemic SFTSV infection likely contribute to the disease pathology,<span><sup>9, 10</sup></span> some studies have shown that direct viral infection of the brain may also play an important role in disease pathogenesis. Evidence from a newborn mouse-infection model has shown that SFSTV can infect microglia to cause inflammasome-mediated neuronal cell death,<span><sup>11</sup></span> which could in part explain how some immunocompromised individuals are more likely to develop severe disease as a result of the infection,<span><sup>4-6</sup></span> whereas most patients who succumb to SFTS show symptoms of severe encephalitis before death. Nevertheless, the molecular mechanisms of virus-induced neuronal pathogenesis and the location of virus-induced brain damage have not been fully characterized.</p><p>Kim et al. have recently published a paper in <i>Journal of Medical Virology</i>,<span><sup>12</sup></span> in which they infected the interferon-alpha receptor knock-out (IFNAR1−/−) adult mice intraperitoneally with SFTSV to deliver the virus systematically and to show that the virus could successfully cross the blood–brain barrier (BBB) to invade the CNS as evidenced by the presence of the viral protein and genomic content being detectable throughout the CNS 4 days after the infection. They showed that SFTSV infected the brainstem and spinal cord of the IFNAR1−/− mice and that A1-reactive astrocytes were activated by virus infection, leading to neuronal cell death. Because the brainstem and spinal cord are regions of the brain that have been associated with respiratory function and motor neurons in IFNAR1−/− mice, SFTSV infection leading to lethal neuroinflammation and neuronal cell death may underlie the cause of disease pathogenesis, pathology, and mortality of some SFTS patients.</p><p>Specifically, the authors showed that viral gene expressions were significantly higher in the olfactory bulb, cortex, cerebellum, brainstem, and spinal cord of the IFNAR1−/− mice. They also characterized the immunological effects of SFTSV infection of the brain and showed that IFNAR deficiency also increased neuronal cell death as demonstrated by a significant decrease in viable neurons by Day-4 postinfection. They showed decreased expression levels of most tested pro-inflammatory cytokines, such as IFNγ, interleukin (IL)1α, IL1β, IL6, and tumor necrosis factor-α. Two exceptions were C1q and C3 cytokines, which were higher in the virus-infected IFNAR1−/− mice. Because these two cytokines have been implicated in the activation of the A1-reactive astrocytes, the authors expanded on this finding by investigating astrocyte signaling and found significantly higher levels of activated astrocytes and A1-astrocyte gene expression in the virus-infected IFNAR1−/− mice.</p><p>The authors also showed that primary astrocytes of SFTSV-infected IFNAR1−/− mice also induced neuronal cell death through the activation of A1-reactive astrocytes. To do this, they investigated the interactions between infected neurons and microglia or astrocytes by isolating primary neurons, microglia, and astrocytes from embryonic or neonatal wild type (WT) and IFNAR1−/− mouse pups and infecting those cells with SFTSV in culture and incubating the infected neurons with the cell-culture media supernatant collected from infected microglia or astrocytes. Conditioned media collected from infected WT and IFNAR1−/− astrocytes but not those from microglia increased neuronal cell death, which reached statistical significance with infected IFNAR1−/− neurons. Furthermore, conditioned media from infected IFNAR1−/− astrocytes had a greater level of increases in neuronal death than those from WT astrocytes. Culturing uninfected neurons with conditioned media from infected microglia or astrocytes demonstrated that the conditioned media supernatant did not pass the infectious virus onto neurons. However, a consideration that was not being addressed by this cell-culture model was the potential impact of direct cell-cell contact, which could be investigated in future experiments in a coculture model.</p><p>It is important to note that while the authors also characterized the rates of morbidity and mortality of several SFTSV genotypes in IFNAR1−/− mice, they did not directly compare those in SFTSV-infected WT mice, and thus, limiting a direct comparison of the potential disease progression due to the virus strains and/or mouse models used. It is also noteworthy that IFNAR1−/− mice have also previously been shown to suffer from enhanced viral breach of the BBB to cause neuronal infection by West Nile virus.<span><sup>13</sup></span> Astrocytes have also been shown to be infected during bunyaviral infection,<span><sup>14-16</sup></span> and studies using other neurotropic viruses have found them to be the first sites of productive infection in the brain.<span><sup>17-21</sup></span> They can also act as longer-lasting viral reservoirs during chronic viral infection,<span><sup>21</sup></span> making their inflammatory responses to viral infection potentially implicated in neuronal pathogenesis throughout the course of the infection. By contrast, productive bunyaviral infection of microglia has so far only been shown in cell culture<span><sup>22-24</sup></span> and in neonatal mice<span><sup>11</sup></span> or humanized mice<span><sup>14</sup></span> despite other studies using bunyaviral infection in adult mice showing microglial activation.<span><sup>15, 24</sup></span> As such, the current study<span><sup>12</sup></span> is an important first step in studying SFTSV-induced neuropathogenesis in adult animals.</p><p>In summary, the authors of the current study<span><sup>12</sup></span> demonstrated that neuronal cell death and immune activation were observed in the brain of adult mice when SFTSV was delivered systemically and could significantly impacted by the loss of IFNAR cellular signaling. Specifically, A1-reactive astrocytes seemed to be more strongly associated with neuronal cell death than microglia. While not directly addressed, it's also possible that A1-reactive astrocytes could be associated with higher levels of SFTSV infection, since the sites of the brain most impacted by IFNAR signaling are in prolonged contact with astrocytes associated with the BBB. This may allow for the high number of susceptible astrocytes concentrated in the BBB to become a site of productive infection upon viral breach of the BBB. Microglia may therefore have a less robust relationship with infection levels and neuronal cell death due to their more diffuse presence throughout the brain. It should also be noted that astrocytes<span><sup>25, 26</sup></span> and microglia<span><sup>27, 28</sup></span> secrete chemokines to recruit peripheral immune cells such as lymphocytes, which have many documented pro- and anti-inflammatory interactions with cells throughout the brain. The contribution of these interactions toward viral control and disease pathogenesis will be another point of study in future investigations of bunyaviral infections.</p><p>This adult mouse model described in the current study<span><sup>12</sup></span> presents an intriguing alternative to neonatal mouse-infection model to study SFTSV-caused disease pathology and pathogenesis. Because microglia in neonatal mice continue to develop in the first couple weeks of life,<span><sup>29-31</sup></span> it is important to develop an alternative animal model, such as the one reported in the current study,<span><sup>12</sup></span> to study SFSTV infection in vivo. This will in turn contribute toward future efforts in developing SFSTV therapeutics and vaccines, such as targeting specific cell types in the brain and optimizing their performance in patients, including immunocompromised individuals, who are most prone to develop severe SFTS disease.</p><p>The authors declare no conflict of interest.</p>","PeriodicalId":16354,"journal":{"name":"Journal of Medical Virology","volume":"96 10","pages":""},"PeriodicalIF":6.8000,"publicationDate":"2024-10-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/jmv.29949","citationCount":"0","resultStr":"{\"title\":\"A1-reactive astrocytes and IFNAR signaling collectively induce neuronal cell death during infection of IFNAR1−/− mice by severe fever with thrombocytopenia syndrome virus\",\"authors\":\"Morgan Brisse,&nbsp;Hinh Ly\",\"doi\":\"10.1002/jmv.29949\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Severe fever with thrombocytopenia syndrome (SFTS) is caused by the SFTS virus (SFTSV), a bunyavirus that is endemic throughout eastern Asia. SFTSV was first discovered in 2009 in central China<span><sup>1</sup></span> and has since infected about 5500 people in China<span><sup>2</sup></span> and approximately 800 each in Japan and South Korea.<span><sup>3</sup></span> The disease (SFTS) is characterized by fever, thrombocytopenia, and central nervous system (CNS) symptoms including headache, vertigo, coma, and encephalitis<span><sup>4, 5</sup></span> which has impacted as many as 45% of SFTS patients.<span><sup>6</sup></span> The mortality rate caused by SFTSV infection varies by region and by year with reported rates as high as 27%.<span><sup>7, 8</sup></span> There are currently no therapeutics or vaccines available for SFTS treatment and prevention.</p><p>While clinical manifestations such as decreased blood flow to the brain resulting from systemic SFTSV infection likely contribute to the disease pathology,<span><sup>9, 10</sup></span> some studies have shown that direct viral infection of the brain may also play an important role in disease pathogenesis. Evidence from a newborn mouse-infection model has shown that SFSTV can infect microglia to cause inflammasome-mediated neuronal cell death,<span><sup>11</sup></span> which could in part explain how some immunocompromised individuals are more likely to develop severe disease as a result of the infection,<span><sup>4-6</sup></span> whereas most patients who succumb to SFTS show symptoms of severe encephalitis before death. Nevertheless, the molecular mechanisms of virus-induced neuronal pathogenesis and the location of virus-induced brain damage have not been fully characterized.</p><p>Kim et al. have recently published a paper in <i>Journal of Medical Virology</i>,<span><sup>12</sup></span> in which they infected the interferon-alpha receptor knock-out (IFNAR1−/−) adult mice intraperitoneally with SFTSV to deliver the virus systematically and to show that the virus could successfully cross the blood–brain barrier (BBB) to invade the CNS as evidenced by the presence of the viral protein and genomic content being detectable throughout the CNS 4 days after the infection. They showed that SFTSV infected the brainstem and spinal cord of the IFNAR1−/− mice and that A1-reactive astrocytes were activated by virus infection, leading to neuronal cell death. Because the brainstem and spinal cord are regions of the brain that have been associated with respiratory function and motor neurons in IFNAR1−/− mice, SFTSV infection leading to lethal neuroinflammation and neuronal cell death may underlie the cause of disease pathogenesis, pathology, and mortality of some SFTS patients.</p><p>Specifically, the authors showed that viral gene expressions were significantly higher in the olfactory bulb, cortex, cerebellum, brainstem, and spinal cord of the IFNAR1−/− mice. They also characterized the immunological effects of SFTSV infection of the brain and showed that IFNAR deficiency also increased neuronal cell death as demonstrated by a significant decrease in viable neurons by Day-4 postinfection. They showed decreased expression levels of most tested pro-inflammatory cytokines, such as IFNγ, interleukin (IL)1α, IL1β, IL6, and tumor necrosis factor-α. Two exceptions were C1q and C3 cytokines, which were higher in the virus-infected IFNAR1−/− mice. Because these two cytokines have been implicated in the activation of the A1-reactive astrocytes, the authors expanded on this finding by investigating astrocyte signaling and found significantly higher levels of activated astrocytes and A1-astrocyte gene expression in the virus-infected IFNAR1−/− mice.</p><p>The authors also showed that primary astrocytes of SFTSV-infected IFNAR1−/− mice also induced neuronal cell death through the activation of A1-reactive astrocytes. To do this, they investigated the interactions between infected neurons and microglia or astrocytes by isolating primary neurons, microglia, and astrocytes from embryonic or neonatal wild type (WT) and IFNAR1−/− mouse pups and infecting those cells with SFTSV in culture and incubating the infected neurons with the cell-culture media supernatant collected from infected microglia or astrocytes. Conditioned media collected from infected WT and IFNAR1−/− astrocytes but not those from microglia increased neuronal cell death, which reached statistical significance with infected IFNAR1−/− neurons. Furthermore, conditioned media from infected IFNAR1−/− astrocytes had a greater level of increases in neuronal death than those from WT astrocytes. Culturing uninfected neurons with conditioned media from infected microglia or astrocytes demonstrated that the conditioned media supernatant did not pass the infectious virus onto neurons. However, a consideration that was not being addressed by this cell-culture model was the potential impact of direct cell-cell contact, which could be investigated in future experiments in a coculture model.</p><p>It is important to note that while the authors also characterized the rates of morbidity and mortality of several SFTSV genotypes in IFNAR1−/− mice, they did not directly compare those in SFTSV-infected WT mice, and thus, limiting a direct comparison of the potential disease progression due to the virus strains and/or mouse models used. It is also noteworthy that IFNAR1−/− mice have also previously been shown to suffer from enhanced viral breach of the BBB to cause neuronal infection by West Nile virus.<span><sup>13</sup></span> Astrocytes have also been shown to be infected during bunyaviral infection,<span><sup>14-16</sup></span> and studies using other neurotropic viruses have found them to be the first sites of productive infection in the brain.<span><sup>17-21</sup></span> They can also act as longer-lasting viral reservoirs during chronic viral infection,<span><sup>21</sup></span> making their inflammatory responses to viral infection potentially implicated in neuronal pathogenesis throughout the course of the infection. By contrast, productive bunyaviral infection of microglia has so far only been shown in cell culture<span><sup>22-24</sup></span> and in neonatal mice<span><sup>11</sup></span> or humanized mice<span><sup>14</sup></span> despite other studies using bunyaviral infection in adult mice showing microglial activation.<span><sup>15, 24</sup></span> As such, the current study<span><sup>12</sup></span> is an important first step in studying SFTSV-induced neuropathogenesis in adult animals.</p><p>In summary, the authors of the current study<span><sup>12</sup></span> demonstrated that neuronal cell death and immune activation were observed in the brain of adult mice when SFTSV was delivered systemically and could significantly impacted by the loss of IFNAR cellular signaling. Specifically, A1-reactive astrocytes seemed to be more strongly associated with neuronal cell death than microglia. While not directly addressed, it's also possible that A1-reactive astrocytes could be associated with higher levels of SFTSV infection, since the sites of the brain most impacted by IFNAR signaling are in prolonged contact with astrocytes associated with the BBB. This may allow for the high number of susceptible astrocytes concentrated in the BBB to become a site of productive infection upon viral breach of the BBB. Microglia may therefore have a less robust relationship with infection levels and neuronal cell death due to their more diffuse presence throughout the brain. It should also be noted that astrocytes<span><sup>25, 26</sup></span> and microglia<span><sup>27, 28</sup></span> secrete chemokines to recruit peripheral immune cells such as lymphocytes, which have many documented pro- and anti-inflammatory interactions with cells throughout the brain. The contribution of these interactions toward viral control and disease pathogenesis will be another point of study in future investigations of bunyaviral infections.</p><p>This adult mouse model described in the current study<span><sup>12</sup></span> presents an intriguing alternative to neonatal mouse-infection model to study SFTSV-caused disease pathology and pathogenesis. Because microglia in neonatal mice continue to develop in the first couple weeks of life,<span><sup>29-31</sup></span> it is important to develop an alternative animal model, such as the one reported in the current study,<span><sup>12</sup></span> to study SFSTV infection in vivo. 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引用次数: 0

摘要

严重发热伴血小板减少综合征(SFTS)由SFTS病毒(SFTSV)引起,SFTSV是一种布尼亚病毒,在整个东亚地区流行。SFTSV 于 2009 年首次在中国中部被发现1 ,至今已在中国感染了约 5500 人2 ,在日本和韩国各感染了约 800 人3 。该病(SFTS)的特征是发热、血小板减少和中枢神经系统(CNS)症状,包括头痛、眩晕、昏迷和脑炎4,5 多达 45% 的 SFTS 患者受到影响6。SFTSV感染导致的死亡率因地区和年份而异,有报道称死亡率高达27%。7, 8 目前还没有治疗和预防SFTS的疗法或疫苗。虽然全身性SFTSV感染导致脑血流量减少等临床表现可能是疾病病理的原因之一,9, 10 但一些研究表明,病毒直接感染大脑也可能在疾病发病机制中发挥重要作用。来自新生小鼠感染模型的证据显示,SFSTV 可感染小胶质细胞,导致炎性体介导的神经元细胞死亡,11 这在一定程度上解释了为什么一些免疫力低下的人更容易因感染而发展成严重疾病,4-6 而大多数死于 SFTS 的病人在死前会表现出严重脑炎的症状。然而,病毒诱导神经元发病的分子机制以及病毒诱导脑损伤的部位尚未完全确定。Kim 等人最近在《医学病毒学杂志》(Journal of Medical Virology)12 上发表了一篇论文,他们用 SFTSV 感染α干扰素受体基因敲除(IFNAR1-/-)的成年小鼠腹腔,以系统性地传递病毒,并证明病毒可成功穿过血脑屏障(BBB)侵入中枢神经系统,感染 4 天后整个中枢神经系统均可检测到病毒蛋白和基因组内容。他们发现,SFTSV感染了IFNAR1-/-小鼠的脑干和脊髓,病毒感染激活了A1反应性星形胶质细胞,导致神经细胞死亡。由于脑干和脊髓是与IFNAR1-/-小鼠呼吸功能和运动神经元相关的大脑区域,SFTSV感染导致致命的神经炎症和神经细胞死亡可能是一些SFTS患者发病、病理和死亡的原因。他们还描述了SFTSV感染大脑的免疫学效应,并发现IFNAR缺乏也会增加神经元细胞的死亡,这表现在感染后第4天存活的神经元明显减少。他们发现大多数测试的促炎细胞因子,如IFNγ、白细胞介素(IL)1α、IL1β、IL6和肿瘤坏死因子-α的表达水平都有所下降。两个例外是 C1q 和 C3 细胞因子,它们在病毒感染的 IFNAR1-/- 小鼠中含量较高。由于这两种细胞因子与 A1 反应性星形胶质细胞的活化有关,因此作者通过研究星形胶质细胞的信号转导进一步扩展了这一发现,并发现在病毒感染的 IFNAR1-/- 小鼠中,活化的星形胶质细胞和 A1-星形胶质细胞基因表达水平明显更高。为此,他们研究了受感染的神经元与小胶质细胞或星形胶质细胞之间的相互作用,方法是从胚胎或新生野生型(WT)小鼠和IFNAR1-/-小鼠幼崽中分离出原发性神经元、小胶质细胞和星形胶质细胞,在培养过程中用SFTSV感染这些细胞,然后用从受感染的小胶质细胞或星形胶质细胞中收集的细胞培养基上清培养受感染的神经元。从受感染的 WT 星形胶质细胞和 IFNAR1-/- 星形胶质细胞中收集的条件培养基增加了神经元细胞的死亡,而从小胶质细胞中收集的条件培养基没有增加神经元细胞的死亡,这在受感染的 IFNAR1-/- 神经元中达到了统计学意义。此外,与来自 WT 星形胶质细胞的条件培养基相比,来自受感染 IFNAR1-/- 星形胶质细胞的条件培养基对神经细胞死亡的增加程度更大。用感染的小胶质细胞或星形胶质细胞的条件培养基培养未感染的神经元表明,条件培养基上清液不会将感染性病毒传递给神经元。不过,这种细胞培养模式没有考虑到细胞-细胞直接接触的潜在影响,这可以在今后的共培养模式实验中进行研究。 值得注意的是,虽然作者也描述了几种 SFTSV 基因型在 IFNAR1-/- 小鼠中的发病率和死亡率,但他们没有直接比较感染 SFTSV 的 WT 小鼠的发病率和死亡率,因此限制了对所使用的病毒株和/或小鼠模型导致的潜在疾病进展的直接比较。另外值得注意的是,IFNAR1-/- 小鼠以前也被证明会受到西尼罗河病毒的影响,病毒突破 BBB 导致神经元感染。在慢性病毒感染过程中,它们还可充当持续时间较长的病毒库21 ,因此在整个感染过程中,它们对病毒感染的炎症反应可能与神经元的发病机制有关。相比之下,尽管其他研究显示成年小鼠的布尼亚病毒感染会激活小胶质细胞,但迄今为止只有在细胞培养22-24 和新生小鼠11 或人源化小鼠14 中显示了小胶质细胞的生产性布尼亚病毒感染、24 因此,本研究12 是研究 SFTSV 诱导的成年动物神经发病机制的重要的第一步。总之,本研究12 的作者证明,在全身注射 SFTSV 后,可在成年小鼠大脑中观察到神经细胞死亡和免疫激活,IFNAR 细胞信号的缺失会对其产生显著影响。具体来说,与小胶质细胞相比,A1 反应性星形胶质细胞似乎与神经细胞死亡的关系更为密切。虽然没有直接涉及,但A1反应性星形胶质细胞也可能与更高水平的SFTSV感染有关,因为大脑中受IFNAR信号影响最大的部位与与BBB相关的星形胶质细胞长期接触。这可能会使集中在 BBB 中的大量易感星形胶质细胞在病毒突破 BBB 时成为产生感染的场所。因此,小胶质细胞与感染水平和神经元细胞死亡之间的关系可能不那么密切,因为它们在整个大脑中的存在更为分散。还应注意的是,星形胶质细胞25、26 和小胶质细胞27、28 会分泌趋化因子,以招募外周免疫细胞(如淋巴细胞),而淋巴细胞与整个大脑中的细胞之间存在着许多记录在案的促炎和抗炎相互作用。这些相互作用对病毒控制和疾病发病机制的贡献将是未来研究布尼亚病毒感染的另一个研究重点。本研究12 中描述的这种成年小鼠模型是研究 SFTSV 引起的疾病病理和发病机制的一种有趣的替代新生小鼠感染模型的方法。由于新生小鼠的小胶质细胞在出生后的前几周仍在继续发育29-31 ,因此开发一种替代性动物模型(如本研究中报道的模型12)来研究体内 SFSTV 感染非常重要。这反过来将有助于未来开发 SFSTV 治疗药物和疫苗的工作,如针对大脑中的特定细胞类型并优化其在患者(包括免疫力低下者,他们最容易患上严重的 SFTS 疾病)中的表现。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A1-reactive astrocytes and IFNAR signaling collectively induce neuronal cell death during infection of IFNAR1−/− mice by severe fever with thrombocytopenia syndrome virus

Severe fever with thrombocytopenia syndrome (SFTS) is caused by the SFTS virus (SFTSV), a bunyavirus that is endemic throughout eastern Asia. SFTSV was first discovered in 2009 in central China1 and has since infected about 5500 people in China2 and approximately 800 each in Japan and South Korea.3 The disease (SFTS) is characterized by fever, thrombocytopenia, and central nervous system (CNS) symptoms including headache, vertigo, coma, and encephalitis4, 5 which has impacted as many as 45% of SFTS patients.6 The mortality rate caused by SFTSV infection varies by region and by year with reported rates as high as 27%.7, 8 There are currently no therapeutics or vaccines available for SFTS treatment and prevention.

While clinical manifestations such as decreased blood flow to the brain resulting from systemic SFTSV infection likely contribute to the disease pathology,9, 10 some studies have shown that direct viral infection of the brain may also play an important role in disease pathogenesis. Evidence from a newborn mouse-infection model has shown that SFSTV can infect microglia to cause inflammasome-mediated neuronal cell death,11 which could in part explain how some immunocompromised individuals are more likely to develop severe disease as a result of the infection,4-6 whereas most patients who succumb to SFTS show symptoms of severe encephalitis before death. Nevertheless, the molecular mechanisms of virus-induced neuronal pathogenesis and the location of virus-induced brain damage have not been fully characterized.

Kim et al. have recently published a paper in Journal of Medical Virology,12 in which they infected the interferon-alpha receptor knock-out (IFNAR1−/−) adult mice intraperitoneally with SFTSV to deliver the virus systematically and to show that the virus could successfully cross the blood–brain barrier (BBB) to invade the CNS as evidenced by the presence of the viral protein and genomic content being detectable throughout the CNS 4 days after the infection. They showed that SFTSV infected the brainstem and spinal cord of the IFNAR1−/− mice and that A1-reactive astrocytes were activated by virus infection, leading to neuronal cell death. Because the brainstem and spinal cord are regions of the brain that have been associated with respiratory function and motor neurons in IFNAR1−/− mice, SFTSV infection leading to lethal neuroinflammation and neuronal cell death may underlie the cause of disease pathogenesis, pathology, and mortality of some SFTS patients.

Specifically, the authors showed that viral gene expressions were significantly higher in the olfactory bulb, cortex, cerebellum, brainstem, and spinal cord of the IFNAR1−/− mice. They also characterized the immunological effects of SFTSV infection of the brain and showed that IFNAR deficiency also increased neuronal cell death as demonstrated by a significant decrease in viable neurons by Day-4 postinfection. They showed decreased expression levels of most tested pro-inflammatory cytokines, such as IFNγ, interleukin (IL)1α, IL1β, IL6, and tumor necrosis factor-α. Two exceptions were C1q and C3 cytokines, which were higher in the virus-infected IFNAR1−/− mice. Because these two cytokines have been implicated in the activation of the A1-reactive astrocytes, the authors expanded on this finding by investigating astrocyte signaling and found significantly higher levels of activated astrocytes and A1-astrocyte gene expression in the virus-infected IFNAR1−/− mice.

The authors also showed that primary astrocytes of SFTSV-infected IFNAR1−/− mice also induced neuronal cell death through the activation of A1-reactive astrocytes. To do this, they investigated the interactions between infected neurons and microglia or astrocytes by isolating primary neurons, microglia, and astrocytes from embryonic or neonatal wild type (WT) and IFNAR1−/− mouse pups and infecting those cells with SFTSV in culture and incubating the infected neurons with the cell-culture media supernatant collected from infected microglia or astrocytes. Conditioned media collected from infected WT and IFNAR1−/− astrocytes but not those from microglia increased neuronal cell death, which reached statistical significance with infected IFNAR1−/− neurons. Furthermore, conditioned media from infected IFNAR1−/− astrocytes had a greater level of increases in neuronal death than those from WT astrocytes. Culturing uninfected neurons with conditioned media from infected microglia or astrocytes demonstrated that the conditioned media supernatant did not pass the infectious virus onto neurons. However, a consideration that was not being addressed by this cell-culture model was the potential impact of direct cell-cell contact, which could be investigated in future experiments in a coculture model.

It is important to note that while the authors also characterized the rates of morbidity and mortality of several SFTSV genotypes in IFNAR1−/− mice, they did not directly compare those in SFTSV-infected WT mice, and thus, limiting a direct comparison of the potential disease progression due to the virus strains and/or mouse models used. It is also noteworthy that IFNAR1−/− mice have also previously been shown to suffer from enhanced viral breach of the BBB to cause neuronal infection by West Nile virus.13 Astrocytes have also been shown to be infected during bunyaviral infection,14-16 and studies using other neurotropic viruses have found them to be the first sites of productive infection in the brain.17-21 They can also act as longer-lasting viral reservoirs during chronic viral infection,21 making their inflammatory responses to viral infection potentially implicated in neuronal pathogenesis throughout the course of the infection. By contrast, productive bunyaviral infection of microglia has so far only been shown in cell culture22-24 and in neonatal mice11 or humanized mice14 despite other studies using bunyaviral infection in adult mice showing microglial activation.15, 24 As such, the current study12 is an important first step in studying SFTSV-induced neuropathogenesis in adult animals.

In summary, the authors of the current study12 demonstrated that neuronal cell death and immune activation were observed in the brain of adult mice when SFTSV was delivered systemically and could significantly impacted by the loss of IFNAR cellular signaling. Specifically, A1-reactive astrocytes seemed to be more strongly associated with neuronal cell death than microglia. While not directly addressed, it's also possible that A1-reactive astrocytes could be associated with higher levels of SFTSV infection, since the sites of the brain most impacted by IFNAR signaling are in prolonged contact with astrocytes associated with the BBB. This may allow for the high number of susceptible astrocytes concentrated in the BBB to become a site of productive infection upon viral breach of the BBB. Microglia may therefore have a less robust relationship with infection levels and neuronal cell death due to their more diffuse presence throughout the brain. It should also be noted that astrocytes25, 26 and microglia27, 28 secrete chemokines to recruit peripheral immune cells such as lymphocytes, which have many documented pro- and anti-inflammatory interactions with cells throughout the brain. The contribution of these interactions toward viral control and disease pathogenesis will be another point of study in future investigations of bunyaviral infections.

This adult mouse model described in the current study12 presents an intriguing alternative to neonatal mouse-infection model to study SFTSV-caused disease pathology and pathogenesis. Because microglia in neonatal mice continue to develop in the first couple weeks of life,29-31 it is important to develop an alternative animal model, such as the one reported in the current study,12 to study SFSTV infection in vivo. This will in turn contribute toward future efforts in developing SFSTV therapeutics and vaccines, such as targeting specific cell types in the brain and optimizing their performance in patients, including immunocompromised individuals, who are most prone to develop severe SFTS disease.

The authors declare no conflict of interest.

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来源期刊
Journal of Medical Virology
Journal of Medical Virology 医学-病毒学
CiteScore
23.20
自引率
2.40%
发文量
777
审稿时长
1 months
期刊介绍: The Journal of Medical Virology focuses on publishing original scientific papers on both basic and applied research related to viruses that affect humans. The journal publishes reports covering a wide range of topics, including the characterization, diagnosis, epidemiology, immunology, and pathogenesis of human virus infections. It also includes studies on virus morphology, genetics, replication, and interactions with host cells. The intended readership of the journal includes virologists, microbiologists, immunologists, infectious disease specialists, diagnostic laboratory technologists, epidemiologists, hematologists, and cell biologists. The Journal of Medical Virology is indexed and abstracted in various databases, including Abstracts in Anthropology (Sage), CABI, AgBiotech News & Information, National Agricultural Library, Biological Abstracts, Embase, Global Health, Web of Science, Veterinary Bulletin, and others.
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