Karwinskia humboldtiana (Kh) also known as tullidora, capulín tullidor or coyotillo, is a poisonous shrub from the Rhamnaceae family. It is distributed throughout the Mexican Republic, South America, Central America and Northern of Colombia (Fernández, 1992). Dreyer et al. (1975) isolated from the endocarp of Kh four dimeric anthracenonic compounds named as T-496, T-514, T-516 and T 544, according to their molecular weights, which have been demonstrated to be responsible for the toxicity of this plant (Dreyer et al., 1975; Waksman et al., 1989, Rivas et al., 1990; Bermúdez et al., 1992, Waksman and Ramirez, 1992).

In the literature, there are numerous reports of accidental human intoxications with Kh fruit (Castillo et al., 1920; Segovia et al., 1972; Bustamante et al., 1978; Puértolas et al., 1984; Arellano et al., 1994; Bermudez et al., 1995; Ocampo et al., 2007). Clinical sign of this intoxication varies according to the amount of fruit ingested. In acute intoxication, respiratory failure and death may occur within 2 to 3 days without paralysis signs. If it is consumed in small quantities or chronic intoxication, after a few weeks of consumption, a clinically flaccid, symmetrical, ascending and progressive paralysis appears which can lead to death (Segovia et al., 1972); or in some cases human can recover slowly from the paralysis (Arellano et al., 1994).

Acute intoxication of Wistar rats with Kh fruit has shown liver disorders and clotting characterized by an increase in aspartate transaminase (AST) and alanine transaminase (ALT), as well as a decrease in II, V, VII and X coagulation factors (Jaramillo et al., 2009). Only there are two in vitro studies in hepatocytes of rat treated with Kh fruit (Wheeler et al., 1971), or with T-514 (Garza-Ocañas et al., 2003) that reported mitochondrial alterations and increase of toxic oxygen radicals. In vivo experimental studies of acute toxicity with purified toxin T-514 administered to different species have reported atelectasis and emphysema, along with infiltration of polymorphonuclear cells in alveolar septa, rupture of capillaries and bleeding (Bermúdez et al., 1986; Sepúlveda et al., 1992). In liver, congestion and massive necrosis were reported, especially with T-514 (Bermudez et al., 1986).

Salazar et al. (2006) reported a model of chronic intoxication with Kh, by the administration of fractionated doses of mature fruit of this plant to Wistar rat. This model reproduces the clinical phases of paresis, paralysis, and recovery that are presented in intoxicated humans when they do not die (Salazar et al., 2006). Recently, we demonstrated a toxic effect of Kh fruit on striatum of Wistar rat using this same intoxication model (Díaz-Pérez et al., 2016). Since there have not been found any studies that describe damage to organs like the liver in this model, the objective was to evaluate histopathological alterations in this organ during chronic intoxication with the fruit of Kh.

Histochemistry

A portion of formalin-fixed tissue was processed for frozen section technique. Histological sections of 6-8 µm thickness were obtained, and stained with Oil Red technique for the histochemistry identification of lipids droplets deposits.

Immunohistochemical evaluation

To distinguish between morphological necrotic alterations induced by Kh intoxication from apoptotic hepatocytes, the TUNEL (TdT-mediated dUTP-biotin Nick-End Labeling) test was performed on 6-8 µm thick sections to detect fragmentation of nuclear DNA, a hallmark of apoptosis (Gavrieli et al., 1992) using the kit TACS™ 2 TdT In situ Apoptosis Detection of Trevigen® (Gaithersburg, MD. USA), according to the instructions of the manufacturer. Nuclei were contrasted with methyl green.

Furthermore, to determine whether Kh intoxication inhibits proliferation of liver cells, histological sections (4-5 µm thick) were incubated with anti-PCNA (Proliferating Cell Nuclear Antigen) monoclonal antibody (1: 200) to identify proliferating cells (Matsumoto et al., 1987; Zhang et al., 1999) using the Envision^® detection system and 3, 3'diaminobenzidine (DAB). PCNA antibody and the detection system were purchased from Dako Cytomation, Inc^® (Carpinteria, Ca. USA). Nuclei were contrasted with Mayer´s hematoxylin. As a negative control, the monoclonal antibody was omitted. The samples were analyzed by light microscope.

Morphometric analysis

To quantify necrotic hepatocytes, the liver parenchyma was divided in hepatic acini or liver Rappaport acini. Hepatic acini (zones 1, 2 and 3) or Rappaport´s hepatic acinus represents a liver lobule that is divided into 3 regions based on their proximity to the distributing veins: zone I has cells closest to the vessels (portal triad) and first to be affected by incoming blood with toxins, zone II  with cells which are second to respond to toxic compounds in blood (in between portal triad and central vein), and zone III with cells near the central vein. Quantization was performed in 24 random fields per group (eight fields/slide, one slide/rat, three rats/group) were chosen from sections stained with H&E and observed with the oil immersion objective (100X). In these fields the normal and necrotic hepatocytes in the 3 zones described for the hepatic acini were quantified.

This methodology  was  also  applied   to  quantify   positive  cells to  TUNEL   test   and   to   PCNA  antibody.  Digital  high-resolution images were obtained with a Nikon Microscope Eclipse 50i, and with the image analysis system Digital Sight dDS-2Mu. Averages and standard deviations (SD) were calculated, and a student´s t-test was performed with the statistics software SPSS program v.16 to compare the control vs experimental groups, a value of p ≤ 0.05 was considered as statistically significant.

Ultrastructure

Simultaneously, other portion of liver was fixed by immersion in solution of Karnowsky-Ito (4% paraformaldehyde, 5% glutaraldehyde, and 0.05% picric acid in 0.1 M PBS pH 7.2-7.4) (Ito and Karnowsky; 1968). Samples were post fixed in 2% aqueous osmium tetroxide, and processed by conventional technique for transmission electron microscopy until their inclusion in epoxy resins to form blocks. Semithin and ultrathin sections were obtained by ultramicrotomy; semithin sections were stained with 1% toluidine blue and analyzed by light microscopy. Ultrathin sections were mounted on copper grids 200 mesh without support medium, and contrasted with 5% uranyl acetate followed by 0.04% lead citrate; samples were analyzed with a Zeiss EM 109 transmission electron microscope.

Morphometric analysis

In the morphometric analysis of liver acini (zones 1, 2 and 3), control group showed only a few hepatocytes damaged per field of view (2,583 ± 1,127; 2,850 ± 0,476 and 1,800 ± 0,519). In the group without paresis, more altered hepatocytes were observed (19,900 ± 2,351; 23,600 ± 5,567 and 17,183 ± 2,133). In paresis group, increased damaged hepatocytes (29,933 ± 4,623; 34,667 ± 1,607 and 34,833 ± 1,985). However, paralysis group presented the highest number of necrotic damage (50,333 ± 4,523; 61,867 ± 2,400 and 61,167 ± 2,478), recovery group showed 8,233 ± 2,315; 8,833 ± 2,182 and 9,633 ± 0,416. Statistical analysis revealed a significant difference in intoxicated group compared with control group (Figure 7A).

The number of positive nuclei in TUNEL analysis in the control group was 2.978 ± 1.321, while in the groups intoxicated with Kh the results are as follows: group without paresis (4.159 ± 0.888), paresis group (4.344 ± 0.432), paralysis group (5.122 ± 0.992) and recovery (3.233 ± 1.523), respectively. When comparing the results of control vs treated groups no significant difference was found for a value of p≤0.05 (Figure 7B).

In proliferation analysis (the number of PCNA positive cells) in control and treated groups, it was observed that control group showed the highest number of positive cells: 26,110 ± 0,639, group without paresis had 22.185 ± 1.054, then paresis group with an average of 18.245 ± 0.732. Group with paralysis showed the lowest amount of positive cells with an average of 12.503 ± 0.521, and finally recovery group showed an amount of 19.024 ± 3,792. All treated groups intoxicated with Kh were significantly different from the control group (p≤0.05; Figure 7C).

Ultrastructural evaluation

In control samples hepatocytes were  observed  with  the cell membrane, nucleus and organelles with normal ultrastructural features (Figure 1F). In groups without paresis and with paresis, necrotic hepatocytes with loss of the continuity of the cell membrane and cytoplasmic extraction (Figure 1G) were observed, as well as sinusoids with vascular congestion (Figure 1H). In these same groups other hepatocytes were observed with small spaces in the cytoplasm corresponding to extracted lipids (Figure 1I). In paralysis group these alterations increase with extended areas of necrotic hepatocytes and hepatocytes with large cytoplasmic vacuoles. In the samples of recovery group only vascular congestion and few and small cytoplasmic vacuoles were observed.

Clinical manifestations, such as weight loss, ocular secretion, hair bristling, weakness, and respiratory difficulty, were analyzed in the rats intoxicated with Kh fruit. These manifestations were present in the paresis group at 48 days, were more evident at 58 days in the paralysis group, and almost all of the symptoms resolved in the recovery group, which only presented piloerection. These results agree with other studies regarding the clinical signs in humans and animals intoxicated with Kh fruit (Padron-Puyou, 1951; Padrón and Velázquez, 1956; Bermúdez et al., 1986; Salazar et al., 2006, García-Juárez et al., 2012).

In this study, we observed a gradual increase of necrotic hepatocytes with abundant vacuolated spaces, as well as vascular congestion and hemorrhagic signs in sinusoids in the groups intoxicated with Kh fruit. These signs agree with the findings reported by Bermúdez et al., (1986) who studied the effect of T-514, one of the toxins isolated from Kh fruit on liver.

 The increasing areas of necrosis in the treated groups were observed in the morphometric analysis, showing the highest amount of necrotic cells in the paralysis group that decreased in the recovery group. This finding has not been described before for chronic intoxication with Kh fruit. It has been described that several plants as Larrea tridentata (Stickel et al., 2000), and Ruta graveolens (Serrano-Gallardo et al., 2013) can cause a hepatotoxic effect similar to the necrotic damage observed in this study.

Another important point is that even though experimental studies of acute intoxication in different animal species with isolated toxins or Kh fruit have reported similar alterations in liver to those observed in the present investigation (Bermúdez et al., 1986; 1992). These studies do not report the progression and recovery of the histopathological damage in the liver observed in the present investigation.

The liver necrosis observed in the present investigation correlates with other experiments reporting that acute administration of ground fruit of Kh causes a significant increase of transaminases AST and ALT levels in serum (Jaramillo et al., 2009), where the increase of these enzymes is indicative of hepatic necrosis.

An in vitro study using the toxin T-514 showed that it suppresses the metabolic activity of mitochondria and it induces the production of reactive oxygen species, both in primary cultures of hepatocytes and microsomes (Garza-Ocañas et al., 2003). Furthermore, an in vitro study performed by Wheeler et al., (1971) using ether extracts of Kh reported that the extracts decreased oxygen consumption, and they produced inhibitory effects. In the same study they observed an uncoupling effect of the respiration chain and an inhibition in the oxidative phosphorylation in mitochondria from rat liver (Wheeler et al., 1971). These alterations could be part of the mechanisms of hepatic cytotoxicity observed in the present investigation.

The recovery of liver necrosis observed in the recovery group at 112 days post-intoxication with Kh, correlates with the high capacity of regeneration of hepatocyte as it has been reported in experimental models treated with chemical agents, where the organ regenerates when the toxic stimulus is removed (Fausto et al., 2000).
Moreover, the hepatic steatosis observed in treated groups in this study has not been reported previously in the chronic intoxication model with Kh fruit. The finding that it was reversible in the recovery group correlates with reported experimental intoxications with chemical agents where hepatic steatosis is a normal response to toxic stimuli, and it is a reversible injury when the stimulus is removed (Riet-Correa et al., 1986; Islas et al., 1991).

On the other hand, it has been proposed that steatosis is caused by an inhibition of the hepatic lipid transportation system (Fromenty et al., 1995; Jaeschke et al., 2002; Xu et al., 2003). These findings suggest that during the chronic intoxication with Kh there is induction of steatosis in the treated groups, but probably the toxic stimulus decreases or ends at the last stages allowing the reversal of hepatic steatosis observed in the recovery group.

In the present study, the areas of necrotic cells were analyzed with the TUNEL assay for chromatin fragmentation, one of the characteristics of apoptosis; and the results showed that few cells were positive in control and intoxicated groups, which demonstrated a normal turnover of hepatocytes. However, no significant difference in the number of positive cells was found among all groups. These results are different compared to findings described in liver of rats treated with Ruta graveolens where necrotic and apoptotic hepatocytes were detected in intoxicated groups (Serrano-Gallardo et al., 2013; Soto-Domínguez et al., 2013). In liver of CD-1 mouse intoxicated with 28 mg of PA1 (toxin T-514)/kg body weight, it was observed that apoptosis was extensive in liver samples (Soto-Domínguez, 2005), in contrast to the present investigation that demonstrated a necrotic effect of Kh fruit.

Using the specific monoclonal antibody anti-PCNA, we observed the largest number of positive cells in the control group; that gradually decreased in intoxicated groups and increased again in the recovery group. This was confirmed in the morphometric analysis. These results are similar to those observed in liver of rats treated with Ruta graveolens where this plant showed an antiproliferative effect in intoxicated groups (Serrano-Gallardo et al., 2013).

The observation of histopathological alterations in the liver of animals intoxicated with Kh fruit, contributes to the knowledge   of  the  toxicological  effect  of  this  plant  to determine whether this intoxication also affects other organs besides the central and peripheral nervous system. Further studies will be required to elucidate the mechanism of damage and recovery in the hepatocytes observed in this study. Currently in vitro and in vivo studies, related to the aforementioned observations are being performed in the present investigation, as well as studies to evaluate the effect of toxins isolated from the Kh seed, such as T-514 administered at different durations and concentrations.  

The authors have not declared any conflict of interests.

This study was supported by a grant from CONACYT for RGG. We acknowledge the work of QCB Rosa Maria Leal G. and Nora Frías Trejo for technical assistance involved in electron microscopy processing and ultramicrotomy, and to Stefanie Galue for reviewing English manuscript.  Present study is dedicated to memory of Ph.D. Julio Sepúlveda-Saavedra (†February 10^th, 2014) Chairman of Histology Department, Faculty of Medicine, UANL until the day of his death.