Ecological , Biological and Genetic Adaptation to Xeric Habitats of Salamandra infraimmaculata on the Southern Border of Its Distribution

In the present mini-review, published and unpublished data that have been collected for more than 40 years on the adaption of Salamandra infraimmaculata to semi-arid environments on the southern border of its distribution are presented. The contribution of the present paper is in building a model based on comparing moist habitats with predictable and relatively constant conditions to semi-arid habitats with relatively dry conditions. Based on these parameters, the model suggests adaptation to semi-arid habitats. More specifically, this model is based on the morphology, biology, behavior, life cycle and physiology of S. infraimmaculata adaptation. By considering these many parameters, one hypothesis was raised and was supported. The adaptation to and selection of semi-arid habitats depend mainly on the terrestrial phase and very little on the aquatic phases. In all of the semi-arid habitats, there are various breeding places where the larvae can grow and complete metamorphosis. The molecular genetic variation among the various areas supports our hypothesis, and the difference in the moist habitats is greater than in the semi-arid environments.


Introduction
One aspect of ecology defines, among the other things, a branch of biology that deals with the relationships and interactions between organisms and their environment.In order to explain the adaption of organisms to a habitat, as many as possible biological parameters that are important to these characteristics must be studied.The Salamandridae family, comprising 16 genera and 66 recognized species, represents one of the G. Degani most diverse groups of extant salamanders.Salamandrids have the largest geographic distribution of any salamander family, extending across the Holarctic continents of Asia, Europe and North America, with a small and recent expansion into North Africa [1].Many aspects of S. infraimmaculata have been studied over the past 40 years on the southern border of its distribution [2].Its adaption to various habitats and areas, including at extreme conditions on the southern border of its distribution, was examined.
The present paper tries to suggest a model of adaptation to xeric habitats of S. infraimmaculata based on published (mini-review) and unpublished data by comparing charac- teristics from the biology, ecology, behavior and physiology of salamanders from different areas and environmental conditions.The objective of the present paper is to discuss various parameters affecting the adaptation of S. infraimmaculata to relatively dry conditions by comparing different habitats and suggesting a model to describe this adaptation.

Distributions
Salamandra infraimmaculata is present in the southeastern and eastern parts of Anatolia, Turkey, northwestern Iran, northern Iraq, Lebanon and northern Israel.Many aspects of S. infraimmaculata, some of which have been described in detail, have been studied over the past 40 years at the southern border of its distribution [2].Based on the sequence analysis of the mitochondrial D-loop region and geological dates, Steinfartz [3] suggested that five major monophyletic groups exist in Europe (S.salamandra, S. infraimmaculata, S. corsica, S. atraand S. lanzai), one S. algira is located in Africa [4], and the salamanders in Israel belong to S. infraimmaculata.The distribution of S. infraimmaculata in the Middle East is presented in Figure 1.In Iran, it is found in an arid sparse cork forest area.In Turkey and Lebanon, it has been found to inhabit damp forests and groves in mountainous or hilly regions, and shelter under leaves, roots or stones not far from water [2] [5] [6] [7] [8].The populations of S. infraimmaculata found in Israel are located in breeding sites in different and isolated sub-regions within relatively short geographical distances: 1) Mount Hermon; 2) Tel Dan; 3) Naftali Mountains; 4) Upper Galilee; 5) Western Galilee [2] [5] [9]- [19]; 6) Lower Galilee [20]; and 7) Mount Carmel [7] [21] [22] (Figure 1).

Different Habitats
On the southern border of S. infraimmaculata distribution, as for many other amphibians, the habitats include two main components-terrestrial habitats and aquatics habitats, where the salamanders can complete their life cycle.During extensive studies carried out on S. infraimmaculata at the extreme conditions, various terrestrial habitats in the areas of the breeding places (Table 1) were described [2] [5] [21] [22].Figure 2 presents various terrestrial habitats of S. infraimmaculata.S. infraimmaculata live in a number of different areas in Israel on the southern border of its distribution in diverse habitats (Figure 1 and Figure 2).They are found mainly at 340 -760 m above sea level (ASL) (Table 1).Only the Tel Dan population is significantly lower at 190 m, where the environmental conditions of this habitat differ from the others.The Upper Carmel is a complex habitat, formed by two vaulted ridges, with notable karst features.The upper ridge consists of Kanoman chalk, with a general height of 500 m, reaching its maximum

Morphological Variations of Terrestrial Salamanders from Variation in Various Habitats
The morphological parameters of salamanders have been studied in detail in Europe [2] [23].A comparison between morphological parameters of Salamandra infraimmaculata in Israel at the southern border of its distribution was made between several populations in different areas: Tel Dan, Upper Galilee (Mount Meron), Western Galilee, and Mount Carmel [24] (Figure 1 and Figure 2).The body size of the salamanders from the Tel Dan population was significantly smaller than that of salamanders from the other areas.No difference was found in mean body measurements, and standard deviation calculated as described in [24] covered the mean between the three areas (Upper Galilee, Western Galilee and Mount Carmel) where the habitats are similar (Figure 3).
More than 400 S. infraimmaculata were measured in four different areas, and the color pattern of the bag spots were one line, two line and scattered at all localities (Figure 4).
In Mount Carmel and Upper Galilee, the scattered pattern was higher, 63% and 59% respectively, compared to Tel Dan and Western Galilee, which was 38% and 18%, respectively (Figure 4).However, no differences were found in spots in the various areas.
In all of the populations, most of the salamanders had four spots on the head (Figure 5), which was the highest of the other patterns in all of the areas (1, 2, 3 or 5); the lowest pattern was 59% in Tel Dan salamanders, and the highest was 86% in Mount Carmel salamanders (Figure 5).Most salamanders from all of the localities are on the ventral black side (Figure 6), about 90%.In a small number of salamanders, a spot was found on the jaw and the ventral side (Figure 6).

Molecular Genetic Variations in Various Areas of S. infraimmaculata in Israel
The  the larvae stages at the breeding places (Figure 1).No variation was found among the three different areas comparing blood plasma proteins [24], or in the 10 enzyme systems with 14 loci [20].However, using different molecular methods, there is strong support of our hypothesis that a variation exists on a genetic level among the methods used (Figure 7).An analysis using various primers with RAPD amplification methods found differences between the different populations in various areas, however, it is very difficult to separate between areas and habitats due to the fact that these methods are not consistent and depend on the primers [26].On the other hand, using mitochondrial   Valley, Western Galilee, Lower Galilee and Mount Carmel) (Figure 1 and Figure 7).
According to these results, the genetic variations change from north to south: a high genetic variation was found between the northern populations (Mount Hermon, Tel Dan) and the southern populations (Lower Galilee and Mount Carmel) (Figure 7).
Different breeding places (springs, rain pools and rock pits) are found in all of the various areas.The genetic differences are not sharp according to breeding place, especially using mitochondrial DNA, rather according to area.Degani

G. Degani
Blank [7] found two major sub-population variations between Mount Carmel and Galilee (Lower Galilee).These methods seem to be more sensitive than AFLP.In summary, the results of AFLP were again similar to what was found in mitochondrial DNA, whereby the genetic variations change from north to south.High genetic variation was found in the northern (Mount Hermon, Tel Dan) and southern (Lower Galilee and Mount Carmel) populations, and not according to breeding type, spring or ponds that were found in most of the areas.

The Life Cycle of S. infraimmaculata
Different stages of S. infraimmaculata have been described in many papers and are shown in Figure 9.The terrestrial life of S. infraimmaculata is described less than the larvae stages at the southern border of its distribution.Salamanders at the southern limit of their distribution are active mainly in the winter (Figure 10).Activity is mostly local, and such activity can also be found in summer.This local activity was studied mainly in the Galilee [9].On hot days, the salamanders are found in hiding places, holes and caves in the ground [2].Migration to breeding places is limited to the hill populations, since the specific environmental conditions at Tel Dan greatly reduce the need for this [10].Activity takes place under conditions of 0˚C -20˚C and 60% -100% RH.Most of the salamanders from Upper Galilee are active at temperatures between 5˚C and 9˚C, and in Tel Dan between 9˚C and 11˚C (Figure 11).However, no difference   was found between populations for activity under various levels of relative air humidity (Figure 12): most activities during day occur at 90% and 100% high humidity levels, which help prevent dehydration of the salamanders during migration to the breeding places.The high activity is found during breeding periods from October to December (Figure 10), and males are more activity than females.Population size was related directly to habitat type [9] [10].The density in Tel Dan adult's population is higher than in the Galilee and changes according to conditions in the habitats [10].The S. infraimmaculata is ovoviviparity (Figure 9), and the larvae are born alive in single and small batches, generally wrapped in their embryonic membrane.Sexual behavior occurs mostly after the oviposition of the larvae at the breeding places and is described for the Upper Galilee population [2].The description of sexual behavior of S. infraimmaculata is presented in Figure 13.The salamanders after mating are solitary and find hiding places to prevent dehydration [18].At the time that the larvae were born, the weights are 0.2 -0.4 g, but they vary in different areas and habitats [18].There are no significant differences between larvae size in the three different areas: Tel Dan, Upper Galilee and Mount Carmel (Figure 14).There is also no difference in growth in the different areas, but there are differences in larvae growth between the various breeding places according to ecological conditions (Figure 15).In streams, as in Tel Dan, or in springs where water temperatures were lower compared to winter pools, the growth rate was lower, and the periods of larvae growth and complete metamorphosis were longer (Figure 15)

Physiological Adaption to Terrestrial Life in Various Habitats
The survival of the terrestrial phase of Amphibia, which is not the ability to prevent dehydration throughout the skin, is through the ability to retain extended dehydration by accumulating water in the body, a high plasma fluid concentration and low metabolism during activity in hiding places in the hot, dry season [20] [21].Most studies on physiological adaption to terrestrial life have been published for Aura, which adapted to more arid environments compared to Urodela [20].The physiological adaption to terrestrial life of S. infraimmaculata was examined by comparing salamanders from two semi-arid environments at the southern border of this species' distribution (Upper Ga-  (Degani 1978(Degani , 1986)).Stage 1: The male moves to the breeding place and raises his body on his front limbs while accelerating his breathing rate.He moves and from time to time changes his standing position.Stage 2: The male chases the females that pass next to him.During the activity period, the male and female are observed moving together.Stage 3: The female is ready for mating, she stops moving, stands and allows the male to penetrate under her body.Stage 4: The male pushes his body below the female and reaches the top of the female while she is straddling him.Stage 5: The amplexus.The female grasps the male with her front limbs, and he raises his front limbs to the sides.Stage 6: The male is under the female and moves his head and tail from side to side, rubbing the ventral epidermis of the female's jaw.The female also moves her head reciprocally in the opposite direction of the male with her head and tail.Stage 7: The male stops his movements and secretes the spermatophore to the ground.The base of the spermatophore is elliptical, measuring some 8 × 6 mm in diameter, with a height of 8 mm.It is transparent, with white pots on the upper part.The movements of the female continue, especially as regards the tail and cloacal region.Stage 8: The male turns his body at 60˚ -90˚ to that of the female.Stage 9: The female continues the movement of the lower part of the body and tail, makes contact with the upper part of the spermatophore, and continues hermovement until penetrating the entrance to the cloaca.Her movement then ceases and the spermatophore is drawn into the body.Stage 10: Amplexus ceases and the couple parts.This process may be repeated more than once.
conditions [30] than salamanders from Tel Dan (Figure 16(A)), and the water loss limit survival of salamanders from Tel Dan was eight days compared to salamanders from Upper Galilee and Mount Carmel, which was 15 days [30].This adaption to terrestrial  (see Section 5).These conditions are found in moist habitats compared to semi-arid habitats in particular at summer time during the hot, dry season.Low metabolism [31], as was found in salamanders from semi-arid habitats compared to moist habitats (Figure 17), gives the advantage of surviving longer periods in hiding places without feeding and activity.The temperatures of S. infraimmaculata from three different areas were studied by comparing the critical thermal maxima (CTM) [27] from different areas.It was found that the CTM was significantly higher in the larvae and metamorphosis of salamanders from both Upper Galilee and Mount Carmel (semi-arid habitats) compared to those from the Tel Dan area (moist habitat) (Figure 18).

Discussion
The ecological adaption of species in natural habitats refers to the study of natural The largest body size [24] of salamanders from semi-arid areas is affected by all the other biological parameters and ecological adaption to semi-arid environments.For example, the ecological adaption helped salamanders reduce their rate of dehydration [30], long movement distances [10] [22], a large number of larvae per batch [18], low metabolism and less energy lost during dry periods [31].On the other hand, the physiological adaption to xeric habitats helped salamanders survive in these habitats and complete the life cycle in the various areas (Figure 9).Other very important conclusions that were found by examining the interaction between all the various ecological and biological parameters are that the adaption is more strongly affected by semi-arid environments in the terrestrial phase and not in the aquatic phase.In all the various areas where S. infraimmaculata habitats are found, there are different breeding places, streams, springs, rock pools and winter pools where larvae of this species are located (Figure 1, Figure 2) [14] [15] [16].However, the ecological conditions in these aquatic places differ.Therefore, the growth rate and complete metamorphosis of salamander larvae are not according to area but to type of breeding place, which is affected by the ecological conditions at each specific breeding place (Figure 15).On the other hand, the physiological adaptation of terrestrial life differs among S. infraimmaculata from various areas (Figure 16) [29] [30] [32].In semi-arid areas, the terrestrial phase  G. Degani

Conclusion
In summary, the proposed model in this paper (Figure 19) showed that in order to understand the heterogeneity adaption among S. infraimmaculata populations in northern Israel's southern border of its distribution, different parameters of different biological and ecological aspects must be examined.This model's adaptation to semi-arid environments was based on the results of morphology, behavior, life cycle and physiology, which might be explained by genetic differences between various habitats, specifically between moist and xeric.
and run all year round, giving rise to the development of rich flora.Most of these brooks are shallow (usually 5 -10 cm) (Figure2(b)).This constant presence of water and dense growth has created an optimal and stable environment for wildlife; flora include northern species such as Farxinus syriaca, and Paliurus spina-christi, as well as species more typical of the Mediterranean region such as Laurus nobilis, Rhamnus alaternus, Quercus ithaburensis and Styrax officinalis.This habitat remains constant throughout the year and is totally different from those in Mount Hermon, Upper Galilee (Figure2(c)), Mount Meron, Lower Galilee (Figure 2(d)), Western Galilee (Figure 2(e)) and Mount Carmel (Figure 2(f)).

Figure 3 .
Figure 3.The measurements of salamanders from various areas.
genetic consequences of habitat fragmentation are an important component of population extinction risk assessment for threatened and endangered species.Intensive studies have been made seeking genetic diversity among various isolated populations of S. infraimmaculata in northern Israel at the southernmost edge of their distribution[2]

Figure 4 .
Figure 4. Spots arrangements on dorsal sides of Salamandra infraimmaculata from various areas.

Figure 5 .
Figure 5. Spots arrangements on heads of Salamandra infraimmaculata from various areas.

Figure 6 .
Figure 6.Ventral side of Salamandra infraimmaculata from various areas.

Figure 7 .
Figure 7. Salamandra infraimmaculata species-RAPD-PCR, nucleotide similarity and divergence of Cyt b and D-loop fragment sequences from different areas in Israel.

Figure 9 .
Figure 9. Life cycle of Salamandra infraimmaculata along the southern border of its distribution:1-salamanders in terrestrial habitats; 2 and 3-salamanders migrating to breeding places; 4-winter ponds in breeding places; 5-female salamanders reaching the breeding place; 6 and 7-salamander oviposition; 8-sexual behavior and mating of salamanders; 9, 10 and 11-larvae of salamanders; 12-salamanders undergoing metamorphosis; 13-juvenile salamanders moving from breeding places to terrestrial life; 14-adult salamanders in a hole in the ground that serves as a hiding place.

Figure 11 .
Figure 11.The activity of salamanders as a function of temperature in two different areas, Upper Galilee and Tel Dan.

Figure 12 .
Figure 12.The activity of salamanders as a function of relative humidity in two different areas, Upper Galilee and Tel Dan.

Figure 13 .
Figure 13.The sexual behavior of Salamandra infraimmaculata(Degani 1978(Degani , 1986)).Stage 1: The life might help salamanders to survive longer in semi-arid habitats compared to moist habitats under extreme conditions where S. infraimmaculata are found.During dehydration, the plasma concentration of salamanders increases mainly by urea, Na + and CL (Figure 16(B)).S. infraimmaculata from semi-arid habitats (Upper Galilee and Mount Carmel) survive at a high plasma concentration compared to salamanders from moist habitats (Tel Dan) [29] [30].S. infraimmaculata are active under very specific conditions

Figure 14 .
Figure 14.Weight as a function of length in newborn larvae at various localities, Tel Dan, Upper Galilee and Mount Carmel.

Figure 17 .
Figure 17.Metabolism (oxygen consumption per gram body weight) of salamanders from different areas.

Figure 18 .
Figure 18.Critical thermal maxima (CTM) of adult S. infraimmaculata from Upper Galilee and Mount Carmel (semi-arid habitats) and the Tel Dan area (moist habitat).

Figure 19 .
Figure 19.Model of different curatrixes showing the adaption of S. infraimmaculata to semi-arid conditions compared to moist conditions.

Table
Communities of Quercus calliprinos and Pistacia palaestina mingle with communities of Genista fasselata and Pinus halepensis, the former predominating at Kfar Damun and the latter at Beit Oren.
. Characteristics of habitats in which Salamandra infraimmaculat larvae were found.Label Name Type Location Height (m.a.s.l.)been preserved over large parts of the range, consist of typical Mediterranean scrub.