Pajenda Sahra, Hevesi Zsofia, Eder Michael, Gerges Daniela, Aiad Monika, Koldyka Oliver, Winnicki Wolfgang, Wagner Ludwig, Eskandary Farsad, Schmidt Alice
Division of Nephrology and Dialysis, Department of Internal Medicine III, Medical University of Vienna, 1090 Vienna, Austria.
Center for Brain Research, Medical University of Vienna, 1090 Vienna, Austria.
Life (Basel). 2023 Jul 7;13(7):1526. doi: 10.3390/life13071526.
Decoy cells that can be detected in the urine sediment of immunosuppressed patients are often caused by the uncontrolled replication of polyomaviruses, such as BK-Virus (BKV) and John Cunningham (JC)-Virus (JCV), within the upper urinary tract. Due to the wide availability of highly sensitive BKV and JCV PCR, the diagnostic utility of screening for decoy cells in urine as an indicator of polyomavirus-associated nephropathy (PyVAN) has been questioned by some institutions. We hypothesize that specific staining of different infection time-dependent BKV-specific antigens in urine sediment could allow cell-specific mapping of antigen expression during decoy cell development. Urine sediment cells from six kidney transplant recipients (five males, one female) were stained for the presence of the early BKV gene transcript lTag and the major viral capsid protein VP1 using monospecific antibodies, monoclonal antibodies and confocal microscopy. For this purpose, cyto-preparations were prepared and the BK polyoma genotype was determined by sequencing the PCR-amplified coding region of the VP1 protein. lTag staining began at specific sites in the nucleus and spread across the nucleus in a cobweb-like pattern as the size of the nucleus increased. It spread into the cytosol as soon as the nuclear membrane was fragmented or dissolved, as in apoptosis or in the metaphase of the cell cycle. In comparison, we observed that VP1 staining started in the nuclear region and accumulated at the nuclear edge in 6-32% of VP1 cells. The staining traveled through the cytosol of the proximal tubule cell and reached high intensities at the cytosol before spreading to the surrounding area in the form of exosome-like particles. The spreading virus-containing particles adhered to surrounding cells, including erythrocytes. VP1-positive proximal tubule cells contain apoptotic bodies, with 68-94% of them losing parts of their DNA and exhibiting membrane damage, appearing as "ghost cells" but still VP1. Specific polyoma staining of urine sediment cells can help determine and enumerate exfoliation of BKV-positive cells based on VP1 staining, which exceeds single-face decoy staining in terms of accuracy. Furthermore, our staining approaches might serve as an early readout in primary diagnostics and for the evaluation of treatment responses in the setting of reduced immunosuppression.
免疫抑制患者尿沉渣中可检测到的诱饵细胞通常是由多瘤病毒(如BK病毒(BKV)和约翰·坎宁安(JC)病毒(JCV))在上尿路中不受控制的复制引起的。由于高灵敏度的BKV和JCV PCR检测方法广泛可用,一些机构对将尿中诱饵细胞筛查作为多瘤病毒相关性肾病(PyVAN)指标的诊断效用提出了质疑。我们假设,对尿沉渣中不同感染时间依赖性的BKV特异性抗原进行特异性染色,可以在诱饵细胞发育过程中实现抗原表达的细胞特异性定位。使用单特异性抗体、单克隆抗体和共聚焦显微镜,对6名肾移植受者(5名男性,1名女性)的尿沉渣细胞进行染色,以检测早期BKV基因转录本大T抗原(LTAg)和主要病毒衣壳蛋白VP1的存在。为此,制备了细胞涂片,并通过对VP1蛋白的PCR扩增编码区进行测序来确定BK多瘤病毒的基因型。LTAg染色从细胞核中的特定部位开始,随着细胞核大小的增加,以蛛网状模式扩散到整个细胞核。一旦核膜破裂或溶解,如在凋亡或细胞周期中期,它就会扩散到细胞质中。相比之下,我们观察到VP1染色始于核区,在6%-32%的VP1阳性细胞中积聚在核边缘。染色穿过近端小管细胞的细胞质,在细胞质中达到高强度,然后以类似外泌体的颗粒形式扩散到周围区域。含有病毒的扩散颗粒粘附在包括红细胞在内的周围细胞上。VP1阳性近端小管细胞含有凋亡小体,其中68%-94%的细胞失去部分DNA并表现出膜损伤,呈现为“幽灵细胞”但仍为VP1阳性。尿沉渣细胞的特异性多瘤病毒染色有助于基于VP1染色确定和计数BKV阳性细胞的脱落情况,其准确性超过单面诱饵染色。此外,我们的染色方法可能作为初步诊断的早期指标,并用于评估免疫抑制降低情况下的治疗反应。
