Metformin and exenatide, originally developed from natural sources, are widely used to treat diabetes.1,2 Indeed, an ethnomedical approach can be used as the basis for drug discovery3 and, once a bioactive product is identified, scientific screening and confirmation should follow. In this context, ancient, northern African, oral testimonies, reported by a patient, attribute glucose-lowering effects to a desert lizard [Uromastyx acanthinura, Bell, 1985; Black Spiny-tailed Lizard, Dab] (UA). Culinary testimonials described that the Uromastyx genus lizards are occasionally eaten by nomads,4,5 but, to our knowledge, the only medicinal uses previously reported are otitis and earache, skin infections and burns.6,7 The aim of this study was to assess the effect of an UA extract on glucose metabolism in an animal model of type 2 diabetes.

An UA preparation, elaborated in Mauritania, was donated to our research group by a patient. Following an ethnomedical approach, an interview was performed and, after pharmacological information was obtained, UA's potential acute and chronic glucose-lowering bioactivity was evaluated in vivo in C57BL/6J mice with diet-induced diabetes.

In vitro testing was initially considered, but the lack of detailed pharmacological information, the heterogeneous nature of the product and the complexity of diabetes itself, made cell-assays a poor solution.

The interview was recorded and dissected to define: product acquisition and preparation, dosage and frequency and route of administration. The whole carcass of UA (head excluded) is grilled and dried, and then minced (0.3–3cm) and incorporated into the diet. People traditionally take a handful of UA once or twice/day with food or water. The oral route was also used in the mice and doses were adjusted to body weight. A dose of 7.66g was estimated for a 60kg-person (0.13g/kg), based on handful measurements of four different people and a range (0.13–1.56g/kg) was tested in the mice.

The different doses of UA diluted in saline or saline alone (saline solution 0.9%, Braun Medical SA, Barcelona), were administered to each animal per body weight, from the starting dose 0.13g/kg, with 2g glucose/kg (Glucose G7528, Sigma–Aldrich Chemie GmbH, Steinheim, Germany) during an oral glucose tolerance test (OGTT; fasting period from 8:00h to 14:00h) (Glucocard G+ metre, GT1280, Arkray-Menarini Diagnostics, Shiga, Japan),8,9 on two different days, following a randomised, crossover design (Fig. 1a).10 C57BL/6 mice were used fed a 60%-fat diet (n=13, 8 males, 16 weeks of age) during the previous 12 weeks (D12492, Brogaarden, Lynge, Denmark), a well established model of type 2 diabetes.11 Doses were increased until the desired effect was noted. In the case of absent effects, the highest dose which was feasible to be administered, based on density, concentration or volume, was selected as an endpoint. The same doses were evaluated simultaneously in the whole group. In the long-term evaluation, the dose which had been most effective in the short-term experiments, was administered daily for 90 days in the high-fat diet (UA group) and compared to high-fat diet alone (control group) (n=10 per group: 50% males, 24 weeks of age, 20 weeks with 60%-fat diet). Body weight (BW), food and water consumption and welfare state were assessed weekly. Morning blood glucose was assessed every 1–2 weeks. HbA1c (DCA, Siemens Healthcare Diagnostics, Deerfield, IL), OGTT and intraperitoneal insulin tolerance tests (IPITT) were performed at baseline and after 3 months’ treatment. Neuropathy was assessed at 3 months by cold allodynia response to acetone,12 where higher nociceptive response scores indicate more severe neuropathy. Regarding sample size, to detect glycaemic variations of at least 30% (α=0.05) with a statistical power of 80%, nine animals per group were deemed necessary.13 The crossover design applied in the acute phase allowed us to reduce this number. In the sub-chronic phase, ten animals per group were used, allowing for a 10% loss and to harmonise sex-distribution.

Figure 1.

Results from the acute evaluation of Uromastyx acanthinura (UA) (solid line, UA; broken line, control). Crossover design of the experiment (a): on day 1, half of the group served as control while on day 2, after a 48h rest, the same group received the treatment. The other half of the group received treatment on day 1 and served as control on day 2. Thus, each treated animal served as its own control. Glucose concentrations (mean and SD) during the oral glucose tolerance test (b) and percentage glucose change from baseline (mean and SD) during the oral glucose tolerance test (c) (*=p<0.05).

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The area under the curve (AUC) of glucose was calculated by the trapezoid rule. For comparisons between groups, Wilcoxon's or Student's tests were used and results were presented as mean (standard deviation) or median [range]. A two-tailed p<0.05 was considered significant (IBM SPSS Statistics Version 18, SPSS Inc., Chicago, IL). Animals were housed in groups of four-five per cage and provided with environmental enrichment. The protocol was performed following National and European requirements (RD 1201/2005, Law 32/2007, EU Directive 2010/63/EU) and was approved by the Animal Welfare Ethics Committee (Comité Ético de Experimentación Animal de la ULPGC; 009/2011).

Oral administration of UA acutely reduced blood glucose in diabetic mice. Paradoxically, long-term administration of UA tended to increase insulin-resistance, food-consumption and mean BW. Symptoms of neuropathy were significantly attenuated in the treated group.

The acute glucose-lowering effects of UA might be explained by the persistence, in its carcass, of a bioactive compound, either synthesised by UA itself, as is the case of Heloderma suspectum (exendin),2 or included in its diet and stored. Indeed, some of the plant species eaten by UA14 have shown glucose-lowering effects.15,16

Food intake and BW increments could explain the discrepancy between the short- and long-term results and the lack of persistence of lower glucose values after the first 5 weeks of treatment. However, other causes can be suggested, including dose (insufficient for the long-term study), pharmacokinetics (short duration of action) or other, unknown metabolic effects.

Insulin-resistance significantly increased in the UA group when compared to controls. Therefore, the improved response to cold allodynia could be due to direct effects on pain or neuropathy itself, and not as side-effect from a better glucose control.

The effects detected in the acute evaluation indicate that the crossover design suited its purpose and allowed a reduction in the number of animals, which is one of the mandatory demands of the principles for laboratory animal handling.17–20 Randomisation of treatment order reduced period bias, as well as bias from possible cumulative effects of UA. The homogeneity of results regardless of the treatment sequence (saline-product vs. product-saline) confirmed that the time left for clearance between treatments was long enough. The crossover design,10 could be an answer to the claim to reduce animal numbers in the pre-evaluation of glucose-lowering and other bioactive compounds.

Only data obtained from animals that were healthy at the end of the study were considered. However, a confounding effect of the development of dermatitis and the distress level cannot be ruled out.21 This dermatitis was not attributed to UA, since both groups were affected by what is a common disorder in C57Bl/6J.21 Although a role of UA in the worse outcome (two losses) cannot be excluded, previous reports describe its topical effects as a treatment for, rather than a cause of dermatitis.6

Finally, our findings suggest direct effects of UA on glucose metabolism and appetite, as well as on pain and/or neuropathy, approaches to consider in further studies. They also support the value of African traditional medicine as a starting point for the screening of new bioactive components.

The authors are not aware of any conflicts of interest related to the contents of this article.