Distribution of tiger salamanders in northern Sonora, Mexico: comparison of sampling methods and possible implications for an endangered subspecies

Many aquatic species in the arid USA-Mexico borderlands region are imperiled, but limited information on distributions and threats often hinders management. To provide information on the distribution of the Western Tiger Salamander (Ambystoma mavortium), including the USA-federally endangered Sonoran Tiger Salamander (Ambystoma mavortium stebbinsi), we used traditional (seines, dip-nets) and modern (environmental DNA [eDNA]) methods to sample 91 waterbodies in northern Sonora, Mexico, during 2015-2018. The endemic Sonoran Tiger Salamander is threatened by introgressive hybridization and potential replacement by another sub-species of the Western Tiger Salamander, the non-native Barred Tiger Salamander (A. m. mavortium). Based on occupancy models that accounted for imperfect detection, eDNA sampling provided a similar detection probability (0.82 [95% CI: 0.56-0.94]) as seining (0.83 [0.46-0.96]) and much higher detection than dip-netting (0.09 [0.02-0.23]). Volume of water filtered had little effect on detection, possibly because turbid sites had greater densities of salamanders. Salamanders were estimated to occur at 51 sites in 3 river drainages in Sonora. These results indicate tiger salamanders are much more widespread in northern Sonora than previously documented, perhaps aided by changes in land and water management practices. However, because the two subspecies of salamanders cannot be reliably distinguished based on morphology or eDNA methods that are based on mitochondrial DNA, we are uncertain if we detected only native genotypes or if we documented recent invasion of the area by the non-native sub-species. Thus, there is an urgent need for methods to reliably distinguish the subspecies so managers can identify appropriate interventions.

Conversion of linoleic acid into arachidonic acid by cultured murine and human keratinocytes

The origin of arachidonic acid (AA) found in the epidermis is not known. Two possibilities exist: either de novo synthesis within the epidermal keratinocyte, or transport of AA formed at distant tissue sites. The current study examined the ability of cultured murine and human keratinocytes to metabolize exogenously added linoleic acid (LA). Conversion of radiolabeled substrate (14C-LA) into 18:3(n-6), 20:2(n-6), 20:3(n-6), and 20:4(n-6) (AA) was noted. The conversion of non-radiolabeled 18:3(n-6) or 20:2(n-6) was also examined and the pattern of metabolites synthesized suggests that the preferred metabolic pathway for conversion of linoleic acid into arachidonic acid is via the classically described pathway in which a delta 6 desaturase constitutes the initial reaction. Although cultured skin fibroblasts are known to convert linoleic acid into arachidonic acid, the current study demonstrates that cultured epidermal keratinocytes can also avidly metabolize exogenous linoleic acid. The ability of cultured keratinocytes, and not of whole epidermis in vivo, to convert linoleic acid into arachidonic acid suggests that specific enzymatic activities may be induced by the tissue culture system itself. Hence, findings of metabolic capabilities in cultured cells may not necessarily be extrapolated to the in vivo situation.

Alterations in fatty acid composition of murine keratinocytes with in vitro cultivation

The availability of methods for the in vitro cultivation of keratinocytes has spawned numerous studies utilizing these systems to analyze epidermal biochemical pathways, e.g., eicosanoid production. To determine whether these culture systems are indeed valid models for studies of eicosanoid products, we analyzed the fatty acid (FA) composition, especially of eicosanoid precursors linoleic acid (LA) and arachidonic acid (AA), of cultured and noncultured mouse keratinocytes. Neonatal mouse epidermal keratinocytes were cultivated in Dulbecco's modification of Eagle's medium + 10% fetal calf serum (FCS). Lipids of the cultivated cells, as well as noncultivated keratinocytes and whole epidermis were extracted in CHCl3:MeOH (2:1) and lipid classes separated by thin-layer chromatography. The FA composition of the total lipid extract as well as of the phospholipid class was determined by gas-liquid chromatography of FA methyl esters. There was a gradual decrease in the LA levels in the cultured cells; by day 5 of culture the cells demonstrated a 4-fold (p less than 0.001) decrease in LA as compared to either noncultured cells or whole epidermis. Levels of AA, on the other hand, remained unchanged during culture. Analysis of the FCS used in the culture medium revealed that the level of LA was 4-fold lower than that of normal mouse serum. Since LA is an essential FA which is not synthesized by the cell, the decreased LA in cultured cells probably results from the paucity of this FA in the FCS-containing culture medium. These studies indicate that keratinocytes cultivated in FCS-containing medium demonstrate profound alterations in levels of LA. Hence, in vitro keratinocyte studies dependent on cellular polyunsaturated FA substrates should be interpreted with caution. The relationship of altered cellular levels of LA on keratinocyte differentiation remains to be determined.