Introduction

The movement of water into and out of cells is a fundamental biological process that keeps the water volume of human body at approximately 70%. Aquaporins (AQPs) are membrane-bound channel proteins distributed in most tissues for the water transport, and there are currently 13 AQPs in mammals [1,2,3]. AQPs are involved in the physiological processes such as regulation in the ovine fetal lung liquid, urinary concentration, body fluid homeostasis, brain function, glandular secretion, skin hydration, male fertility, hearing, and vision [3, 4]. Moreover, AQPs are also associated with several pathological disorders such as cancer progression, angiogenesis, Parkinson’s disease, and disc herniation [5,6,7,8].

From the forensic aspects, pulmonary thromboembolism resulting from deep vein thrombosis (DVT) is one of the major causes that occurs sudden unexpected death. We explored the pathophysiology of DVT from the viewpoints of both forensic and molecular pathology [9, 10]. Subsequently, we found key roles of several cytokines such as IFN-γ, TNF-α, and IL-6 in the resolution of DVT using knockout mice [11,12,13]. It is one of the important matters to determine how long before a wound has been sustained or a thrombus has been formed [14,15,16,17,18,19,20]. Thus, we reported several specific cell and markers for the estimation of thrombus age [9, 10].

Previously, we demonstrated the forensic significances of AQP-1 and AQP-3 from the determination of wound vitality or ages [21, 22]. In the present study, we immunohistochemically examined intrathrombotic appearance of AQP-1 and AQP-3 and discussed the possibility of their application to thrombus age estimation in forensic practices.

Materials and methods

Stasis-induced deep vein thrombus model

Specific pathogen-free 8- to 10-week-old male BALB/c mice were purchased from SLC (Shizuoka, Japan). Intravenous thrombus was induced as described previously [10,11,12,13]. Under the deep anesthesia, an incision was made on the abdominal wall, and the inferior vena cava (IVC) was exposed and ligated. At the indicated time intervals, mice were euthanized by the inhalation of over-dose isoflurane, and thrombus samples were obtained. At each time point, 5 mice were used. All animal experiments were approved by the Committee on Animal Care and Use of the Wakayama Medical University.

Histopathological analyses and immunohistochemistry

Thrombus samples were fixed in 4% formaldehyde buffered with PBS (pH 7.2), and 4- μm-thick paraffin-embedded sections were made [10]. For histopathological analyses, deparaffinized sections were stained with Masson’s trichrome (MT) staining [11,12,13, 23]. As described previously, immunostaining of AQP-1, AQP-3, and F4/80 was performed by Ventana Discovery® XT (Ventana Medical Systems, Inc., AZ, USA) using rabbit anti-AQP-1 polyclonal antibodies (pAbs) (sc-20810, 2 μg/ml; Santa Cruz Biotechnology, Inc., Santa Cruz, CA, USA), goat anti-AQP-3 pAbs (sc-9885, 2 μg/ml; Santa Cruz Biotechnology, Inc., Santa Cruz, CA, USA), and rat anti-F4/80 monoclonal Ab (40 μg/ml; Serotec, Oxford, UK) [10, 11, 13].

Double-color immunofluorescence analysis

Double-color immunofluorescence analysis of AQP-3 and F4/80 was performed by Ventana Discovery® XT [13]. Deparaffinized sections were incubated in a combination of rabbit anti-AQP-3 pAbs and rat anti-F4/80 mAb. After incubation with FITC-labeled (3 μg/ml; Jackson ImmunoResearch Laboratories, West Grove, PA) and Cy3-labeled secondary pAbs (0.75 μg/ml; Jackson ImmunoResearch Laboratories), the sections were observed by fluorescence microscopy [15, 17].

Morphometrical analysis of AQP-1+ area and collagen deposition

Intrathrombotic collagen deposition was semi-quantitated as the blue area in MT-stained sections [23]. AQP-1+ brown area in the thrombus was evaluated by ImageJ analysis software Ver. 1.50a (National Institute of Health, USA) and expressed as the percentage of the whole thrombus area [24].

Semi-quantitative evaluation

Intrathrombotic AQP-3+ cells and F4/80+ cells were evaluated semi-quantitatively, as described previously [10, 11, 25]. Immunopositive cells were enumerated in five high-power fields (hpf; × 1000) within the thrombus; the total numbers in the five fields were combined. All measurements were performed by two examiners without prior knowledge.

Statistical analysis

All data are presented as the mean ± SEM. To compare the values between two groups, Student’s t test or Welch t test was performed. All statistical analyses were performed using Statcel4 software.

Results

Intrathrombotic appearance of AQP-1+ area and collagen content area

In the thrombus samples with the post-ligation intervals of 1 to 7 days, numerous AQP-1+ erythrocytes were found. Thereafter, AQP-1+ erythrocyte areas were gradually decreased in accordance with the thrombus ages. However, AQP-1+ erythrocyte was still detected in 21-day-old thrombus samples (Fig. 1a). In mirror to these observations, MT-stained blue area was hardly found in the early time points after IVC ligation, and the blue area was increased in the thrombus sample aged 7 days or more (Fig. 1b). We performed the semi-quantitation assay to obtain the AQP-1+ area and MT-stained blue area to the thrombus formation area on the cross section of the thrombi. In thrombus samples with the post-ligation intervals of 1 to 5 days, AQP-1+ areas and MT-stained blue area were over 70% and < 10%, respectively. At 7 days after the IVC ligation, AQP-1+ areas became less than 50%, eventually decreasing to 11% at 21 days (Table 1, Fig. 1c). On the contrary, MT-stained blue area started to increase from the peripheral area of the thrombi at day 7 or more, reaching to > 80% at day 21 (Table 1, Fig. 1c). In thrombus samples aged less than 7 days, AQP-1+ area was dominant to MT-stained blue area (Fig. 1c). Moreover, AQP-1-positive signals were detected in the endothelial cells of neovessels later than 10 days after the IVC ligation (Fig. 2a), and the number of AQP-1-positive neovessels increased time dependently (Fig. 2b).

Fig. 1
figure 1

(a) Immunohistochemical detection of murine intrathrombotic AQP-1 and (b) Masson’s trichrome staining images of murine thrombi at 3, 7, 14, and 21 days after IVC ligation. Original magnification: × 100. (c) Relationship of intrathrombotic AQP-1+ area and collagen+ area

Table 1 Mean intrathrombotic AQP-1+ area and collagen content area in each thrombus age group (n = 4–5)
Fig. 2
figure 2

(a) AQP-1+ cells in the endothelial cell of intrathrombotic neovessels. (b) Changes of intrathrombotic AQP-1+ neovessels numbers after IVC ligation

Intrathrombotic distributions of AQP-3+ cell and macrophages

In 1-day-old thrombus samples, AQP-3+ cells could not be detected in thrombi. At 3 days after the IVC ligation, AQP-3+ cells started to appear from the peripheral area. Thereafter, the positive cell number progressively increased and reached to a peak at 10 days after the IVC ligation (Fig. 3). Moreover, we found that AQP-3 was colocalized in F4/80+ macrophages (Fig. 4a). Although there was no thrombus sample with the AQP-3+ cell number of > 30 in the post-ligation intervals of ≤ 7 days, all of thrombus samples aged 10 and 14 days had the AQP-3+ cell number of > 30 (Table 2, Fig. 3b). Calculating the ratio of AQP-3+ macrophage number to total macrophage number, almost of thrombus samples aged ≤ 7 days had the ratio of < 50%.

Fig. 3
figure 3

(a) Immunohistochemical detection of murine intrathrombotic AQP-3 at 1, 7, 10, and 14 days after IVC ligation and (b) changes in intrathrombotic AQP-3+ cell numbers after IVC ligation. Original magnification: × 400

Fig. 4
figure 4

(a) Double-color immunofluorescence analysis of AQP-3 in intrathrombotic F4/80+ macrophages. Fourteen days after IVC ligation; original magnification × 400. (b) Changes in the AQP-3+ cell number and the F4/80+ macrophages numbers

Table 2 Mean intrathrombotic AQP-3+ cell number and ratio of AQP-3+/macrophage in each thrombus age group (n = 4–5)

Discussion

It is needless to say that forensic medicine is not just basic but applied medicine that diagnoses the cause of death, the mechanism of wounding, and wound ages. Thus, in order to improve the accuracy and objectivity of diagnosis, advanced scientific and medical knowledges and information should be applied to forensic practices. AQPs are indispensable molecule for water movement in mammals, which prompted us to explore the relationship between drowning and AQP expression. In 2009, our research group firstly examined intrapulmonary AQP5 expression from the aspects of differentiation between freshwater and saltwater drowning [26]. Thereafter, there are several studies on the AQP-associated forensic practices such as brain edema, pulmonary edema, and hyper- or hypothermia [27,28,29].

It is well known that there are similar points such as inflammatory cell migration, neovascularization, and collagen accumulation in pathophysiology between skin wound healing and thrombus formation/resolution. Thus, we found several common markers for the determination of both wound ages and thrombus ages. In addition to the differentiation between freshwater and saltwater drowning [30, 31], we demonstrated the usefulness of AQP-1 and AQP-3 in the determination wound vitality or ages [21, 22]. These observations implied that AQPs might be involved in thrombus formation/resolution. Thus, we tried to examine the expression of AQP-1 and AQP-3 in stasis-induced venous thrombi of mice. Subsequently, we found out the possibility that aquaporins contributed in thrombogenesis/the resolution process.

AQP-1 is widely distributed in various organs, tissues, and cells such as red blood cells, proximal tubular cells, lung, secretory glands, skeletal muscle, and peritoneum except for the central nervous system [32,33,34,35]. On the other hand, aquaporin 1 contributes to the coagulation function of the platelet, and the possibility that an aquaporin inhibitor results in anticoagulant action is suggested [36]. The inhibition of AQP-1-dependent water exchange augmented the pressure-induced hemolysis in human erythrocytes, thus indicating that AQP-1 played protective roles in pressure-induced hemolysis [37, 38].

In early phase, thrombus samples were mainly composed of erythrocytes, followed by leukocyte migration. Eventually, thrombus samples were organized by collagen accumulation and neovascularization [39]. In line with these changes, AQP-1+ area on erythrocytes was widely observed and gradually disappeared time dependently. Moreover, AQP-1 was expressed in dermal capillaries [40], indicating that AQP-1 might be associated with angiogenesis but not collagen accumulation [41]. Also, chronic hypertension resulted in the enhancement of AQP-1 expression in vascular endothelium [42]. Actually, we could detect AQP-1+ signals in intrathrombotic neovessels.

AQP-3 is expressed in keratinocytes and epithelial cells of air way and urinary [43,44,45,46]. Several lines of accumulating evidence implied that AQP-3 played important roles in tissue repair [39, 47, 48]. AQP-3 promoted keratinocyte migration, and AQP-3-deficient mice showed impaired skin wound healing [39]. Similarly, the lack of AQP-3 in corneal cells retarded corneal reepithelialization [47]. Moreover, AQP-3 was also associated in enterocyte proliferation through glycerol transportation. Thus, the administration of dextran sulfate or acetic acid causes more severe colitis in the absence of AQP-3 [48]. In the present study, we found that intrathrombotic macrophages expressed AQP-3, suggesting that AQP-3 might contribute to macrophage migration. This is supported by the evidence that the function of the macrophage was disturbed in AQP-3 null mice, eventually resulting in a high mortality due to bacterial peritonitis [49].

In the present study, we could confirm intrathrombotic expression of AQP-1 and AQP-3, implying that both AQP-1 and AQP-3 were involved in thrombogenesis and resolution. From the aspects of forensic pathology, both AQPs would be available markers for thrombus age estimation. Temporal changes of intrathrombotic AQP-1 expression were mirror image to that of intrathrombotic collagen accumulation. When the intrathrombotic AQP-1+ area was as large as the intrathrombotic collagen area or smaller, it would indicate a thrombus age of ≥ 10 days. AQP-3+ cell number of > 30 would indicate a thrombus age of 10–14 days. Moreover, AQP-3 was expressed by a part of intrathrombotic macrophages. The ratio of AQP-3+ macrophage number to total macrophage number would be useful for the determination of thrombus ages. Actually, in thrombus samples without intrathrombotic organization, the ratio of < 50% would indicate a thrombus age of ≤ 7 days.

Additionally, coronavirus disease 2019 (COVID-19) rapidly spread across the entire globe rapidly. The patients with COVID-19 develop acute lung injury, resulting in the progress to respiratory failure. The initial coagulopathy of COVID-19 presents with prominent elevation of D-dimer and fibrin/fibrinogen degradation products, while abnormalities in prothrombin time, partial thromboplastin time, and platelet counts are relatively uncommon in initial presentations [50, 51]. On the autopsy findings, pulmonary embolism and DVT were observed in the patients with COVID-19 [52,53,54,55]. COVID-19 brought down the thrombosis and led to sudden death. In our previous papers on the IVC stasis-induced murine DVT model, we found out the roles of the cytokines, chemokines, and their receptors which developed in neutrophils and macrophages, which constituted a thrombus formation and resolution [11, 12]. The thrombus age determination would be important in order to clarify the relationship between COVID-19 infection and thrombogenesis using human thrombus samples and to diagnose the cause of death correctly.