Assessment of Cytological Effects of Food Preservative Potassium Metabisulphite to Allium cepa

With the unprecedented development of the food industry, food preservatives have gained a leading role in food processing. In this study, investigations were carried out to assess the cytological effects of potassium metabisulphite (PMB) to onion (Allium cepa), one of the most used plants for determining the cytotoxic and genotoxic effects of different chemicals. Meristematic roots of A. cepa were treated with PMB solutions in different concentrations, ranging from 10 mg/l to 35 mg/l for 6, 12 and 24 h alongside an untreated control. The quantified parameters for the different concentrations of the PMB were mitotic index (MI %), mitosis phases index (PI %) and total abnormalities index (TAI %) meaning chromosomal aberrations and nuclear abnormalities. The results indicated that PMB reduced MI in A. cepa with increasing the concentrations and time exposure as compared with the untreated control. Thus, at concentration of 10 35 mg/l PMB, these values were reduced from 8.34% to 4.81% (6 h); 7.18% to 2.35% (12 h) and 4.12 to 1.43 (24 h). Also, the TAI value increased with increasing PMB concentrations and time: 0.51% to 9.98% (6 h), 7.11% to 19.84% (12 h) and 17.79 to 41.21 (24 h). The types of abnormalities induced by PMB in A. cepa meristematic cells were micronucleus, C-metaphase, star anaphase, stickiness, laggards, fragments, binucleated cells and pulverised nucleus. These alarming findings indicate the cytotoxic and genotoxic effect of PMB to A. cepa and suggest necessity to adopt more natural alternatives for food preservation in the future.


Introduction
For centuries before the medieval period, and for centuries afterward, human beings in all parts of the world used a variety of methods to preserve foods for later consumption [1]. Due to the very high demand for processed food products, the demand for substances to facilitate the processing of the raw material, the preservation over a longer period of the food products has increased. At the beginning of the 19th century, a rapid rise in the use of chemical additives has been observed [2].
Food additives, marked with E letter-due to the alignment with the European Union norms [3] can be identified in most processed food products. They are used in all branches of the food industry. Regulation (EC) No 1169/2011 of the European Parliament and of the Council provide food information that shall pursue a high level of protection of consumers' health and interests by providing a basis for final consumers to make informed choices and to make safe use of food, with particular regard to health, economic, environmental, social and ethical considerations [3].
The usefulness of food additives is that they maintain the quality and safety of the products for a longer period of time, maintain or improve the taste of the products, ensure the control of the acidity and alkalinity of the products, maintain the consistency of the products, the aroma or colour of the food, etc. [4].
Preservatives, one of the categories of food additives, protect food by slowing down the damage caused by bacteria, fungi, yeast and air. A preservative is defined as any substance which is capable of inhibiting, retarding, or arresting, the growth of micro-organisms, of any deterioration of food due to micro-organisms, or of masking the evidence of any such deterioration [5].
Food safety is a global problem, and a large number of consumers worldwide face a variety of food safety risks each year [6]. Scientific food management is an important tool to avoid severe health issues [7] [8] [9]. Food safety affects consumer food choice in ways that are different from other dimensions of quality [10]. The use of chemical preservatives is regulated by maximum permitted levels. These amounts vary between countries. When the food additives are given to organisms in excessive amounts, they may cause toxic reactions [11] [12] [13].
Certain food additives may have harmful effects and may lead to headache, nausea, weakness, difficulty in breathing [14] or gastrointestinal, dermatologic and neurologic adverse reactions [15] [16].
Potassium metabisulphite (PMB) also known as potassium pyrosulphite or potassium disulphite is a white crystalline powder with a sulphur odour and is chemically very similar to sodium metabisulphite, with which it is sometimes used interchangeably. The use of PMB is not universally accepted [17] but is widely used in the wine industry, and in food it is found in many types of biscuits and cakes. It can also be found in fast food and pickles, dried fruits, etc.
This study aimed to estimate the cytotoxic and genotoxic potential of PMB

Microscopic Preparations
After each exposure time, the meristematic roots were cut with sharp blade, fixed in Carnoy fixative (ethyl alcohol:glacial acetic acid 3:1) and hydrolysed in 1N hydrochloric acid (HCl) for 5 min. The roots tips were stained using 5 ml of Schiff Reagent for 45 min at room temperature and then were crushed in drop of 2% acetocarmine. The microscopic preparations were performed by squash technique. For this purpose, the slide was placed and coverslip on a double layer of paper towel, then paper was folded over the coverslip and squash down on the coverslip with a strong vertical pressure, using thumb. The pressure was applied to squash the root tip into a single cell layer. Five replicates were made for each concentration.
The microscopic slides were examined at 1000× magnification.

Statistical Analyses
Minimum 1000 cells were scored in the roots tip for each concentration. The

Mitotic Index and Mitosis Phases Index
Treatment of the meristematic roots of A. cepa with PMB showed a strong mitodepressive effect even in lower concentrations ( Table 1). The

Cytological Abnormalities
Genotoxic effect of PMB to A. cepa was manifested by the appearance of several types of cytological abnormalities (chromosomal aberrations and nuclear anomalies) ( Table 2). Their percentages increased as the concentration of the PMB and the exposure time increased when compared with the control. The main types of abnormalities induced by PMB in A. cepa meristematic cells were micronucleus, C-metaphase, star anaphase, stickiness, laggards, fragments, binucleated cells and pulverised nucleus, aspects highlighted on the microscopic images through arrows. Thus, changes that occur at the chromosome or nuclear level are indicated ( Figure 1). The most common type of abnormality identified was micronucleus followed by stickiness.
E. Rosculete et al.   Figure 1. Some cytological abnormalities identified in meristematic cells of A. cepa exposed to different concentration of PBM food preservative: cells with C-metaphase indicated by arrow (a) (b); micronucleus indicated by arrows (c) (d); sticky metaphase (bigger arrow) with lost chromosomes (smaller arrow) (e); laggard (arrow above) and fragments (arrow below) in disturbed metaphase (f); cell with star anaphase indicated by arrow (g); binucleated cell indicated by arrow (h) and pulverised nucleus indicated by arrows (i).

Discussion
In the present investigation, we studied the cytotoxic and genotoxic effects of E. Rosculete et al.
PMB food preservative in A. cepa root-tips using MI (%) and TAI (%) as the toxicological endpoints. The mitotic index decreased considerably in the different treatments. It showed the mitodepressive activity of PMB. Cytological studies revealed statistically significant (p < 0.05) inhibition in mitotic index with an increase in concentration of the PMB when compared with the control. These findings are in agreement with other studies which show the mitodepressive effect of different preservatives in A. cepa cells [11] [24]. This could be due to a movement made slower of cells from synthesis phase to mitosis phase of the cell cycle as a result of PMB exposure and its potential to interfere with intracellular components of A. cepa. As some authors suggest, decrease in mitotic index might be due to inhibition of DNA synthesis [25] or a blocking in the G2-phase of the cell cycle, preventing the cell from entering mitosis [24].
MI is an acceptable measure of cytotoxicity in all living organisms [26] [27]. The cytotoxicity level can be determined by the decreased rate of MI. In this respect, a decrease of MI below 22% in comparison to controls can have a lethal impact on the organism [28], while a decrease below 50% usually has sublethal effects [29]. In present study, the percentage of anaphase and telophase was decreased when compared with the control groups after the all PMB concentrations and exposure time. This may attribute to the blocking of cell division by the PMB food preservative at the end of the metaphase stage and suggests delaying cell cycle.
Generally speaking, for genotoxicity assessment the magnitude of genetic risk to organisms by environmental agents/ chemicals under a specified level of exposure must be determined [30]. Some authors consider that the plant system can detect the genotoxicity and cytotoxicity more quickly than animal bioassays being optimal to environmental monitoring in general [31].
In our study, cytotoxic and genotoxic effects of PMB on A. cepa meristematic roots were indicated at all tested concentrations and all exposure times. All PMB treatments significantly decreased the mitotic activity and increased the frequency of total abnormalities (chromosomal aberrations and nuclear anomalies). In terms of the frequency, the most identified abnormalities were micronuclei in cell interphase. Hamedo and Abdelmigid (2009) considered that micronucleus formation is one of the most economical and most effective ways in determining genotoxicity of different chemicals [32]. Also, the micronucleus assay is recognized as one of the most successful and reliable assays for genotoxic carcinogens that act by causing genetic damage [33] [34] or the most prevalent biomarker of chromosomal defects induced by genotoxic agents [35]. An individual predisposition to diseases is correlated with micronucleus incidence [36] [37]. A variety of genotoxic agents may induce micronucleus formation leading to cell death, genomic instability, or cancer development [35] [38]. A micronucleus may arise from a whole lagging chromosome or an acentric chromosome fragment detaching from a chromosome after breakage which does not integrate in the daughter nuclei [39]. Pollution of the environment with various chemical American Journal of Plant Sciences agents increases the frequency of micronucleus formation in both plants and animal cells, increasing the ecotoxicological risk [40] [41]. In accordance with Gömürgen (2005), such genetic damages like micronuleus may have clastogenic effect of their inducers [23]. Micronuclei were considered as an indication of a true mutation effect [42] thus, the high percentage of the micronuclei induced by PMB on A. cepa cells suggest their mutagenic effect. Therefore, the appearance of micronuclei in meristematic cells of A. cepa may suggest caution in the consumption of foods which containing PMG food preservative.
Chromosome stickiness may result from entanglement of chromatin fibers, which fall to condense properly in preparation for cell division [43] [44] [45]. Stickiness can cause serious changes in nucleic acids physico-chemical properties or chromatin condensation of the nucleus [46]. Also, sticky chromosomes can cause loss of genetic material and subsequently, the cell-division process occurs irregularly, with some chromosomes not adhering to the assembled chromosomal complex and being lost during the cell cycle. Laggard's chromosomes induction is due to delayed termination of chromosome end or because of failure of chromosomal movement and attributed to the spindle apparatus [46] [47].
A growing number of consumers are aware of the potential negative health effects of chemical preservatives, which has prompted the food industry to find natural products used and developed as alternatives [48]. Concerns about synthetic preservatives have caused increasing interest in natural antioxidants [49]. Some study showed that natural antimicrobial extracts from hot peppers are rich in antioxidant and antiradical compounds [49]. Also, the mixture of natural antibacterial extracts could be used as food treatment to extend the shelf-life of pre-cut carrots by two days without affecting their sensory properties [2].
A. cepa is one of leading vegetable crops in the world and the allelopathic potential and biological characteristics of this species have been deeply investigated. Allelopathy refers to the beneficial or harmful effects of one plant on another plant through releasing of biochemical from plant parts [50] [51] [52] [53]. Plants have the ability to synthesize chemical compounds (active principles), their active properties being correlated with the biochemical mechanisms of human metabolism [54] and this must be taken into account in the future when processing and preserving food. Depending on plant type and bacterial strain, essential oil derivatives could have a high antibacterial activity and they can behave as natural preservatives [2].
The processing of some foods like the fresh-cut fruits includes key preservation techniques, namely the use of packaging with modified atmosphere that can be improved with the addition of antimicrobial and antioxidant agents allowing, in combination with low storage temperature, an extended shelf life, at the same time preserving their nutritional and organoleptic proprieties [55]. From this point of view, the use of edible coatings supplemented with essential oils can constitute in the future a promising approach to improve both preservation and safety of fresh-cut fruits [55].
As some authors stated, if food preservatives is judiciously used, they are an important group of substances that help to raise the keeping quality, the nutritional value and the aesthetic qualities of foods [56] [57]. On the other hand, technological processes that are used for food preservation may affect the functional, nutritional, and biological properties of food proteins [58]. In the future, new preservation technologies will have the purpose not just working to increase longevity; they will work also functioning to sustain the same qualities of the food that make it desirable in the first place [55]. The physical characteristics and chemical composition of the food will no longer be compromised during the preservation process [55].

Conclusion
All present results revealed the predominance cytotoxic and genotoxic effect of PMB on A. cepa, which were concentrated and time-dependent. Our study about PMB food preservative showed that it cannot assess the actual level of risk for consumer's health. However, disturbed mitosis and the large number of cytological abnormalities identified in meristematic cells of A. cepa exposed to action of this food preservative can be a warning sign and suggest necessity to adopt more natural alternatives for food preservation in the future. We intend to test other usual chemical preservatives in terms of their cytological effects on meristematic cells of plants.